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base: ydy0615:feat/unitree_g1
Branches Tags
ydy0615:main ydy0615:feat/vla-jepa ydy0615:fix/topreward-docs-symlink ydy0615:feat/smolvla-on-steerable ydy0615:auto/update-uv-lock ydy0615:docs/complete-docs-redesign ydy0615:chore/add-dependabot-github-actions ydy0615:feat/language-annotation-pipeline ydy0615:feat/depth-integration ydy0615:rebot-mit-mode ydy0615:docs/model-card-improvements ydy0615:feat/robometer-rm ydy0615:pr/3545 ydy0615:fix/vlabench-ci-faster ydy0615:chore/colored-cli ydy0615:feat/depth-frames ydy0615:feat/audio_dataset ydy0615:feat/leader_activate_teleop ydy0615:feat/leader-arm-intervention-pr2596 ydy0615:feat/rl-leader-arm-intervention ydy0615:test/rl-processor ydy0615:codex/fix-rollout-relative-actions ydy0615:codex/rollout-relative-action-fixes ydy0615:codex/model-profiling ydy0615:feat/lerobot-rollout-fix ydy0615:codex/robotwin-curobo-fix ydy0615:feat/decouple_record_script ydy0615:feat/libero-benchmark ydy0615:docs/feetech-wrist ydy0615:feat/benchmark-ci-clean ydy0615:dependabot/uv/uv-de6dee5cc7 ydy0615:feat/minimal_default_install ydy0615:fix/loading-errors ydy0615:test/my_little_pr ydy0615:security-fix/-github-workflows-claude-yml-1775744456 ydy0615:feat/health-dashboard ydy0615:fix/claude-code-action-precommit ydy0615:add-claude-github-actions-1775661722130 ydy0615:fix/images-transforms ydy0615:feat/eval-parallel ydy0615:fix/ci_token ydy0615:fix/re-enable-sac-normalization ydy0615:feat/eval-thread-safe-policy ydy0615:feat/umi ydy0615:feat/relative_umi ydy0615:feat/add-auto-subtask-annotation ydy0615:feat/unitree_g1_sonic ydy0615:feat/robomme-integration ydy0615:feat/dataset-visualization-tools ydy0615:feat/RL-token ydy0615:chore/dataset_error_handling ydy0615:lerobot_ui ydy0615:feat/multi-dataset ydy0615:feat/libero-plus-integration ydy0615:fix/dataset-conversion ydy0615:feat/robocasa-benchmark ydy0615:chore/fix-datasets ydy0615:dependabot/pip/pip-915b9422ef ydy0615:pr/2545 ydy0615:security-fix/-github-workflows-full_tests-yml-1772811260 ydy0615:feat/add-pi05 ydy0615:feat/trim-episode-start-main ydy0615:feat/trim-episode-start-skip-short ydy0615:security-fix/-github-workflows-full_tests-yml-1772788552 ydy0615:test/nightly-2 ydy0615:test/nightly-fix ydy0615:security-fix/-github-workflows-nightly-yml-1772713391 ydy0615:fix/pandas-parquet-dataset-v30 ydy0615:security-fix/-github-workflows-full_tests-yml-1772699180 ydy0615:feat/robot-teleop-pipeline ydy0615:feat/dynamixel-protocol-1 ydy0615:user/khalil-meftah/root-v1-native ydy0615:user/khalil-meftah/root-v2-native ydy0615:pr-2996 ydy0615:feat/slurm-mirror-dataset-script ydy0615:fix-missing-teleop-imports ydy0615:feat/improve_serial_exo ydy0615:user/khalil-meftah/pr/2822 ydy0615:fix/ci-tv5 ydy0615:feat/trim_episodes ydy0615:envs/support-more-args ydy0615:openarms_wallx_rebased_3 ydy0615:feat/mirror ydy0615:exp/wave-token ydy0615:pr-2888 ydy0615:tmp/fold_training ydy0615:feat/dart ydy0615:feat/training_time_rtc ydy0615:exp/videovla_additions ydy0615:refactor/lerobot_train_rabc ydy0615:exp/video-encoder ydy0615:feat/anyskin-sensors ydy0615:fix/force_cpu_nit ydy0615:openarms_wallx_rebased_2 ydy0615:feat/inter ydy0615:feat/try_interpolation ydy0615:feat/openarm_relative_ee ydy0615:feat/pifast ydy0615:feat/pi0fast ydy0615:pr-1411 ydy0615:peft-precommit-fixes ydy0615:feat/add-hirobot ydy0615:openarms_wallx_rebased ydy0615:openarms_tmp_rebase ydy0615:refactor/replay-buffer-gymnasium-terminology ydy0615:feat/add_record ydy0615:feat/test_hi ydy0615:feat/optimizer_fusion ydy0615:feat/bilateral_teleop ydy0615:jade/slurm-job ydy0615:feat/compare_state_action ydy0615:feat/unitree_g1_threading_fix ydy0615:feat/behavior-1k ydy0615:feat/convert_egodex ydy0615:feat/unitree_g1 ydy0615:fix/add-xvla-ci-main ydy0615:feat/sarm_uniform-sampling ydy0615:fix/unitree_g1_robot_linter ydy0615:feat/add_openarm ydy0615:feat/fracapuano-behavior-1k ydy0615:convert-hdf5 ydy0615:feat/rtc-docs ydy0615:feat/dummy ydy0615:fix/libero-reset ydy0615:feat/fracapuano-distributed-dataset-merging ydy0615:feat/add_dsrl ydy0615:fix/conversion_script_images ydy0615:fix/dataset_training_performance ydy0615:feat/multi-process-cameras ydy0615:feat/custom_teleop ydy0615:tmp/add_openarm ydy0615:tmp/wip_dsrl ydy0615:docs/add-env-api ydy0615:feat/accelerate-melt-gpus ydy0615:feat/add_macos_ci ydy0615:fix/keyboard_ee_teleop ydy0615:revert/raise_empty_feature_processor_normalize ydy0615:patch/fracapuano-improve-reward-classifier ydy0615:feat/add-memory-benchmark-pipeline ydy0615:feat/add_pi_pipeline_accell ydy0615:feat/add-memory-benchmark ydy0615:feat/add-multidataset-training ydy0615:feat/profile-streaming ydy0615:feat/add-sim-libero-pipeline ydy0615:smolvla-dev ydy0615:feat/validate_pi_libero ydy0615:fix/aloha ydy0615:user/CarolinePascal/2025_09_12_update_video_benchmark ydy0615:fracapuano/12_09_25-update-dataset-docs ydy0615:fix/pi0 ydy0615:chore/improve_tests_processor ydy0615:feat/add_processor_to_eval ydy0615:feat/convert_rlds ydy0615:user/michel-aractingi/2025-9-4-fix-reachy2-tests ydy0615:ci/convert_pipeline_1869 ydy0615:ci/convert_pipeline_1862 ydy0615:user/michel-aractingi/2025-9-4-downgrade-grpc-version ydy0615:accelerate-multi-gpu-support ydy0615:ci/convert_pipeline_1841 ydy0615:mypy_support ydy0615:feature/general_r_learning ydy0615:mrussi/glove_visualizer ydy0615:user/michel-aractingi/2025-8-13-dataset_tools ydy0615:user/michel-aractingi/2025-8-12-so101_leader_follower ydy0615:feat/accelerate-support ydy0615:backup/user/michel-aractingi/2025-08-01-gym-pipeline ydy0615:user/azouitine/fix-dtype-normalization ydy0615:user/fracapuano/2025_07_28_fix_test_datasets ydy0615:feat/add-biteleop-so101 ydy0615:user/michel-aractingi/defualt_viz_v2.1 ydy0615:pr-1484 ydy0615:user/fracapuano/2025_07_10_inf_endpoints ydy0615:danaaubakirova/25_06_2025 ydy0615:user/michel-aractingi/dataset_v3_backup ydy0615:merge_main_hopejr ydy0615:user/fracapuano/2025_06_19_droid_v3 ydy0615:user/fracapuano/2025_06_14_chunk_difference_regularize ydy0615:user/michel/datasetv3_remi_backup ydy0615:user/azouitine/2025-06-05-hil-normalization-check ydy0615:user/michel-aractingi/2025-06-02-docs-for-hil-serl ydy0615:origin/fix/record_policy_action_dict ydy0615:last-port-hil-backup ydy0615:test/robot_refactor_experiments ydy0615:user/aliberts/2025_04_19_refactor_cameras ydy0615:user/pepijn/2025_05_05_lekiwi_dual_teleop ydy0615:user/michel-aractingi/tmp-hil-serl-rebase ydy0615:user/michel-aractingi/tmp-port-hil-serl-new ydy0615:user/mrussi/2025_01_09_hope_junior ydy0615:2025_04_11_vla_eval ydy0615:user/mrussi/2025_04_12_hopejr ydy0615:user/azouitine/2025-4-8-softmax-grasp-critic ydy0615:user/michel_aractingi/2024-04-04-grasp-critic ydy0615:feat/add_rerun ydy0615:user/michel_adil/dump_hil_serl ydy0615:user/pepijn/2025_03_18_fix_rotation_so100_docs ydy0615:user/pepijn/2025_03_11_weighted_sampling ydy0615:torchcodec-cpu ydy0615:user/pepijn/2025_03_11_focal_loss ydy0615:feat/autopolicy ydy0615:user/mshukor/2025_02_25_accelerate ydy0615:user/michel-aractingi/2024-02-21-hilserl-threading-to-mp ydy0615:user/michel-aractingi/2024-02-18-hilserl-cache-embedding ydy0615:user/michel-aractingi/2025-01-21-server-client-arch ydy0615:user/michel-aractingi/2025-01-18-port-rlds-example
ydy0615:v0.5.1 ydy0615:v0.5.0 ydy0615:v0.4.4 ydy0615:v0.4.3 ydy0615:v0.4.2 ydy0615:v0.4.1 ydy0615:v0.4.0 ydy0615:v0.3.3 ydy0615:v0.3.2
...
compare: ydy0615:feat/add-hirobot
Branches Tags
ydy0615:main ydy0615:feat/vla-jepa ydy0615:fix/topreward-docs-symlink ydy0615:feat/smolvla-on-steerable ydy0615:auto/update-uv-lock ydy0615:docs/complete-docs-redesign ydy0615:chore/add-dependabot-github-actions ydy0615:feat/language-annotation-pipeline ydy0615:feat/depth-integration ydy0615:rebot-mit-mode ydy0615:docs/model-card-improvements ydy0615:feat/robometer-rm ydy0615:pr/3545 ydy0615:fix/vlabench-ci-faster ydy0615:chore/colored-cli ydy0615:feat/depth-frames ydy0615:feat/audio_dataset ydy0615:feat/leader_activate_teleop ydy0615:feat/leader-arm-intervention-pr2596 ydy0615:feat/rl-leader-arm-intervention ydy0615:test/rl-processor ydy0615:codex/fix-rollout-relative-actions ydy0615:codex/rollout-relative-action-fixes ydy0615:codex/model-profiling ydy0615:feat/lerobot-rollout-fix ydy0615:codex/robotwin-curobo-fix ydy0615:feat/decouple_record_script ydy0615:feat/libero-benchmark ydy0615:docs/feetech-wrist ydy0615:feat/benchmark-ci-clean ydy0615:dependabot/uv/uv-de6dee5cc7 ydy0615:feat/minimal_default_install ydy0615:fix/loading-errors ydy0615:test/my_little_pr ydy0615:security-fix/-github-workflows-claude-yml-1775744456 ydy0615:feat/health-dashboard ydy0615:fix/claude-code-action-precommit ydy0615:add-claude-github-actions-1775661722130 ydy0615:fix/images-transforms ydy0615:feat/eval-parallel ydy0615:fix/ci_token ydy0615:fix/re-enable-sac-normalization ydy0615:feat/eval-thread-safe-policy ydy0615:feat/umi ydy0615:feat/relative_umi ydy0615:feat/add-auto-subtask-annotation ydy0615:feat/unitree_g1_sonic ydy0615:feat/robomme-integration ydy0615:feat/dataset-visualization-tools ydy0615:feat/RL-token ydy0615:chore/dataset_error_handling ydy0615:lerobot_ui ydy0615:feat/multi-dataset ydy0615:feat/libero-plus-integration ydy0615:fix/dataset-conversion ydy0615:feat/robocasa-benchmark ydy0615:chore/fix-datasets ydy0615:dependabot/pip/pip-915b9422ef ydy0615:pr/2545 ydy0615:security-fix/-github-workflows-full_tests-yml-1772811260 ydy0615:feat/add-pi05 ydy0615:feat/trim-episode-start-main ydy0615:feat/trim-episode-start-skip-short ydy0615:security-fix/-github-workflows-full_tests-yml-1772788552 ydy0615:test/nightly-2 ydy0615:test/nightly-fix ydy0615:security-fix/-github-workflows-nightly-yml-1772713391 ydy0615:fix/pandas-parquet-dataset-v30 ydy0615:security-fix/-github-workflows-full_tests-yml-1772699180 ydy0615:feat/robot-teleop-pipeline ydy0615:feat/dynamixel-protocol-1 ydy0615:user/khalil-meftah/root-v1-native ydy0615:user/khalil-meftah/root-v2-native ydy0615:pr-2996 ydy0615:feat/slurm-mirror-dataset-script ydy0615:fix-missing-teleop-imports ydy0615:feat/improve_serial_exo ydy0615:user/khalil-meftah/pr/2822 ydy0615:fix/ci-tv5 ydy0615:feat/trim_episodes ydy0615:envs/support-more-args ydy0615:openarms_wallx_rebased_3 ydy0615:feat/mirror ydy0615:exp/wave-token ydy0615:pr-2888 ydy0615:tmp/fold_training ydy0615:feat/dart ydy0615:feat/training_time_rtc ydy0615:exp/videovla_additions ydy0615:refactor/lerobot_train_rabc ydy0615:exp/video-encoder ydy0615:feat/anyskin-sensors ydy0615:fix/force_cpu_nit ydy0615:openarms_wallx_rebased_2 ydy0615:feat/inter ydy0615:feat/try_interpolation ydy0615:feat/openarm_relative_ee ydy0615:feat/pifast ydy0615:feat/pi0fast ydy0615:pr-1411 ydy0615:peft-precommit-fixes ydy0615:feat/add-hirobot ydy0615:openarms_wallx_rebased ydy0615:openarms_tmp_rebase ydy0615:refactor/replay-buffer-gymnasium-terminology ydy0615:feat/add_record ydy0615:feat/test_hi ydy0615:feat/optimizer_fusion ydy0615:feat/bilateral_teleop ydy0615:jade/slurm-job ydy0615:feat/compare_state_action ydy0615:feat/unitree_g1_threading_fix ydy0615:feat/behavior-1k ydy0615:feat/convert_egodex ydy0615:feat/unitree_g1 ydy0615:fix/add-xvla-ci-main ydy0615:feat/sarm_uniform-sampling ydy0615:fix/unitree_g1_robot_linter ydy0615:feat/add_openarm ydy0615:feat/fracapuano-behavior-1k ydy0615:convert-hdf5 ydy0615:feat/rtc-docs ydy0615:feat/dummy ydy0615:fix/libero-reset ydy0615:feat/fracapuano-distributed-dataset-merging ydy0615:feat/add_dsrl ydy0615:fix/conversion_script_images ydy0615:fix/dataset_training_performance ydy0615:feat/multi-process-cameras ydy0615:feat/custom_teleop ydy0615:tmp/add_openarm ydy0615:tmp/wip_dsrl ydy0615:docs/add-env-api ydy0615:feat/accelerate-melt-gpus ydy0615:feat/add_macos_ci ydy0615:fix/keyboard_ee_teleop ydy0615:revert/raise_empty_feature_processor_normalize ydy0615:patch/fracapuano-improve-reward-classifier ydy0615:feat/add-memory-benchmark-pipeline ydy0615:feat/add_pi_pipeline_accell ydy0615:feat/add-memory-benchmark ydy0615:feat/add-multidataset-training ydy0615:feat/profile-streaming ydy0615:feat/add-sim-libero-pipeline ydy0615:smolvla-dev ydy0615:feat/validate_pi_libero ydy0615:fix/aloha ydy0615:user/CarolinePascal/2025_09_12_update_video_benchmark ydy0615:fracapuano/12_09_25-update-dataset-docs ydy0615:fix/pi0 ydy0615:chore/improve_tests_processor ydy0615:feat/add_processor_to_eval ydy0615:feat/convert_rlds ydy0615:user/michel-aractingi/2025-9-4-fix-reachy2-tests ydy0615:ci/convert_pipeline_1869 ydy0615:ci/convert_pipeline_1862 ydy0615:user/michel-aractingi/2025-9-4-downgrade-grpc-version ydy0615:accelerate-multi-gpu-support ydy0615:ci/convert_pipeline_1841 ydy0615:mypy_support ydy0615:feature/general_r_learning ydy0615:mrussi/glove_visualizer ydy0615:user/michel-aractingi/2025-8-13-dataset_tools ydy0615:user/michel-aractingi/2025-8-12-so101_leader_follower ydy0615:feat/accelerate-support ydy0615:backup/user/michel-aractingi/2025-08-01-gym-pipeline ydy0615:user/azouitine/fix-dtype-normalization ydy0615:user/fracapuano/2025_07_28_fix_test_datasets ydy0615:feat/add-biteleop-so101 ydy0615:user/michel-aractingi/defualt_viz_v2.1 ydy0615:pr-1484 ydy0615:user/fracapuano/2025_07_10_inf_endpoints ydy0615:danaaubakirova/25_06_2025 ydy0615:user/michel-aractingi/dataset_v3_backup ydy0615:merge_main_hopejr ydy0615:user/fracapuano/2025_06_19_droid_v3 ydy0615:user/fracapuano/2025_06_14_chunk_difference_regularize ydy0615:user/michel/datasetv3_remi_backup ydy0615:user/azouitine/2025-06-05-hil-normalization-check ydy0615:user/michel-aractingi/2025-06-02-docs-for-hil-serl ydy0615:origin/fix/record_policy_action_dict ydy0615:last-port-hil-backup ydy0615:test/robot_refactor_experiments ydy0615:user/aliberts/2025_04_19_refactor_cameras ydy0615:user/pepijn/2025_05_05_lekiwi_dual_teleop ydy0615:user/michel-aractingi/tmp-hil-serl-rebase ydy0615:user/michel-aractingi/tmp-port-hil-serl-new ydy0615:user/mrussi/2025_01_09_hope_junior ydy0615:2025_04_11_vla_eval ydy0615:user/mrussi/2025_04_12_hopejr ydy0615:user/azouitine/2025-4-8-softmax-grasp-critic ydy0615:user/michel_aractingi/2024-04-04-grasp-critic ydy0615:feat/add_rerun ydy0615:user/michel_adil/dump_hil_serl ydy0615:user/pepijn/2025_03_18_fix_rotation_so100_docs ydy0615:user/pepijn/2025_03_11_weighted_sampling ydy0615:torchcodec-cpu ydy0615:user/pepijn/2025_03_11_focal_loss ydy0615:feat/autopolicy ydy0615:user/mshukor/2025_02_25_accelerate ydy0615:user/michel-aractingi/2024-02-21-hilserl-threading-to-mp ydy0615:user/michel-aractingi/2024-02-18-hilserl-cache-embedding ydy0615:user/michel-aractingi/2025-01-21-server-client-arch ydy0615:user/michel-aractingi/2025-01-18-port-rlds-example
ydy0615:v0.5.1 ydy0615:v0.5.0 ydy0615:v0.4.4 ydy0615:v0.4.3 ydy0615:v0.4.2 ydy0615:v0.4.1 ydy0615:v0.4.0 ydy0615:v0.3.3 ydy0615:v0.3.2

42 Commits
feat/unitr ... feat/add-h

Author SHA1 Message Date
Jade Choghari
18ddc67714 add more changes 2025-12-17 18:23:23 +00:00
Pepijn
b229e7df28 Add voice example 2025-12-17 16:31:25 +01:00
Jade Choghari
8e05dc9a7a add fast tokenizer support 2025-12-16 11:28:27 +00:00
Jade Choghari
fddd044306 add eos token in tokenizer, working 2025-12-14 14:54:07 +00:00
Jade Choghari
522396a15a more 2025-12-13 21:02:36 +00:00
Jade Choghari
7e232fb114 more changes 2025-12-13 21:02:07 +00:00
Jade Choghari
dc452f37e0 add training 2025-12-12 10:27:28 +00:00
Jade Choghari
3c11946755 allow loading high level tasks 2025-12-10 16:22:54 +00:00
Jade Choghari
8edbd5b55e working step 2 2025-12-10 09:53:29 +00:00
Jade Choghari
025c2b2831 make step 2 work 2025-12-09 16:53:01 +00:00
Jade Choghari
c8eee4ea16 add step2 2025-12-09 12:28:46 +00:00
Jade Choghari
9091b68d86 make it work 2025-12-08 14:19:15 +00:00
Jade Choghari
3568df8a35 woking on qwen 2025-12-08 14:03:47 +00:00
Jade Choghari
a811945336 add 2025-12-08 12:21:41 +01:00
Jade Choghari
0a10d377b5 add Dlabel script 2025-12-08 12:21:01 +01:00
Michel Aractingi
0217e1e3ad Fix dataset aggreagation for multi video datasets' (#2550) 2025-12-05 16:09:25 +01:00
Vladislav Sovrasov
d79dd6d31f Add a documentation page with a brief intro to hw backends (#2385) 2025-12-05 13:32:58 +01:00
Steven Palma
56b43cc888 fix(scripts): missing so101 import (#2577) 
* fix(scripts): missing so101 import

Co-authored-by: Skyler <skylerwiernik@gmail.com>

* fix(scripts): move urdf to cli args

* refactor(scripts): improve find_joints_limits

---------

Co-authored-by: Skyler <skylerwiernik@gmail.com>
 2025-12-03 18:20:26 +01:00
Kevin Thomas
77fe5a09ed fix(docs): argument typo (#2361) 
Co-authored-by: Steven Palma <imstevenpmwork@ieee.org>
 2025-12-03 17:57:18 +01:00
Austin King
89ae7813a7 Reorganize assembly instructions setup before assembly (#2333) 
Motors should be set up before the arm is assembled. 

Moving the entire motor setup section before the part cleaning and assembly section.

Signed-off-by: Austin King <shout@ozten.com>
Co-authored-by: Steven Palma <imstevenpmwork@ieee.org>
 2025-12-03 17:56:58 +01:00
./c²
e003108cf8 Fix link to lerobot-train script in documentation (#2466) 
* Fix link to lerobot-train script in documentation

Signed-off-by: ./c² <cagataycali@icloud.com>

* Update link to lerobot record script

Signed-off-by: ./c² <cagataycali@icloud.com>

---------

Signed-off-by: ./c² <cagataycali@icloud.com>
Co-authored-by: Steven Palma <imstevenpmwork@ieee.org>
 2025-12-03 15:46:26 +01:00
Steven Palma
5766eea377 fix(docs): remove duplicated package in install instructions (#2573) 2025-12-03 15:45:56 +01:00
Steven Palma
f8a4cf225b feat(robots): add earth rover robot support (#2575) 
Co-authored-by: somthecoder <sbaner64@gmail.com>
Co-authored-by: randomSmarts <Aarshsmittal@gmail.com>
Co-authored-by: Hassoonu <halsae2@illinois.edu>
Co-authored-by: Saketh06 <saketh.kantipudi@gmail.com>
Co-authored-by: sairajshetye <sairajshetye2@gmail.com>
Co-authored-by: Khalil Meftah <kmeftah.khalil@gmail.com>
 2025-12-03 15:36:22 +01:00
Jade Choghari
43b0f17eb9 feat(policies): Add X-VLA (#2405) 
* first commit

* more fixes

* add franka action

* update testing script

* add changes

* update files

* logits matching

* add imagenet as a norm type

* logits matching atol1e-2

* more eval fixes

* more changes

* xvla works on libero

* remove seed

* more refactoring

* more fixes

* more changes

* more changes

* more fixes

* migrate policy revert

* major pre-commit cleanup

* renaming

* revert to self.transformer

* refactor

* new changes

* clean

* update libero

* more changes

* make it work

* more changes:

* remove imagenet dependency

* style

* more

* more refactor

* remove proprio

* add loss

* more

* more

* add freeze/unfreeze options

* add testing

* upgrade transformers version

* update testing

* add installation

* remove .sh file

* fix testing

* silent linter in xvlatest

* fix failing test

* upgrade test, fix failing

* fix testing

* more fixes to testing

* require cuda in tests

* temp check

* add xvla docs

* fix styling

* update libero doc

* remove timm dep

* add different dtype support

* remove timm skip

* remove white lines

* Enhance X-VLA finetuning documentation with optimizer details (#2537)

Added detailed instructions for implementing a custom optimizer and modifying parameter retrieval for X-VLA finetuning.

Signed-off-by: Jinliang Zheng <54488861+2toinf@users.noreply.github.com>

* fix style

* iterate on review

* iterate on cpilot

* revert xvla dep

* free up ci

* test(xvla): remove main test (#2565)

* Add xvla custom optim and dtype (#2567)

* add custom optim

* add custom optim

* add auto mode

* more changes

* add identity to all

* add auto

* release

* add docs

* make image smaller docs

* smaller image in doc

* evan smaller image doc

* finalize doc

---------

Signed-off-by: Jinliang Zheng <54488861+2toinf@users.noreply.github.com>
Signed-off-by: Steven Palma <imstevenpmwork@ieee.org>
Co-authored-by: Jinliang Zheng <54488861+2toinf@users.noreply.github.com>
Co-authored-by: Michel Aractingi <michel.aractingi@huggingface.co>
Co-authored-by: Steven Palma <imstevenpmwork@ieee.org>
 2025-12-03 15:29:14 +01:00
Steven Palma
b0b755471b Revert "Earth Rover Mini Plus integration (#2544)" (#2574) 
This reverts commit 35c5a27352.
 2025-12-03 14:43:07 +01:00
s1lent4gnt
35c5a27352 Earth Rover Mini Plus integration (#2544) 
* feat: Add EarthRover Mini Plus robot integration with Frodobots SDK

* refactor: Clean up

* refactor: Remove VirtualCamera implementation for EarthRover Mini Plus integration

* fix: Reduce timeout for camera requests

* fix: Add empty cameras dict for compatibility with recording script

* refactor: Remove record.py script for EarthRover Mini Plus use lerobot_record instead

* refactor: Update documentation for EarthRover Mini Plus integration

* refactor keyboard teleoperation

* refactor: Remove angular velocity

* docs: Add documentation for EarthRover Mini Plus integration

* Add earthrover_mini_plus robot to replay and teleoperate scripts

* refactor: Update stop key from Space to X

* refactor: Implement caching for camera frames and robot telemetry data

* refactor

* refactor: Replace string literals with constants for action and observation keys

* Add Earth Rover Mini to robots section in documentation

Co-authored-by: somthecoder sbaner64@gmail.com
Co-authored-by: randomSmarts Aarshsmittal@gmail.com
Co-authored-by: Hassoonu halsae2@illinois.edu
Co-authored-by: Saketh06 saketh.kantipudi@gmail.com
Co-authored-by: sairajshetye sairajshetye2@gmail.com
 2025-12-03 14:24:57 +01:00
vinoyang
afb90e17e7 doc: fix wrong package name in installation doc (#2513) 2025-12-03 13:36:59 +01:00
Daniel San José Pro
9ec9ee781a feat(policies): Allow users to register 3rd party policies - pip install lerobot_policy_mypolicy (#2308) 
* feat: Register external policies

* ruff fix

* move policy util functions to policy factory

* refactor register_third_party_devices -> register_third_party_plugins

* feat: Update docs with bring your own policies

* Improve docs for new policies

* fix: Inconsistent quotation marks

* fix: Remove print statement

* fix: wrong base class name in documentation

* fix: Handle better how the models are parsed

* fix: precommit passing

* Update docs/source/bring_your_own_policies.mdx

Co-authored-by: Steven Palma <imstevenpmwork@ieee.org>
Signed-off-by: Daniel San José Pro <42489409+danielsanjosepro@users.noreply.github.com>

---------

Signed-off-by: Steven Palma <imstevenpmwork@ieee.org>
Signed-off-by: Daniel San José Pro <42489409+danielsanjosepro@users.noreply.github.com>
Co-authored-by: Steven Palma <imstevenpmwork@ieee.org>
 2025-12-03 12:09:24 +01:00
Md. Muhaimin Rahman
0b497fc37d Make transport module Mypy Compliant [issue#1731] (#2433) 
* latest

* Delete =3.0.0

Signed-off-by: Md. Muhaimin Rahman <sezan92@gmail.com>

* Update src/lerobot/transport/utils.py

Signed-off-by: Md. Muhaimin Rahman <sezan92@gmail.com>

---------

Signed-off-by: Md. Muhaimin Rahman <sezan92@gmail.com>
Co-authored-by: Steven Palma <imstevenpmwork@ieee.org>
 2025-12-02 22:12:15 +01:00
Michel Aractingi
797cd2725a fix pi05 forward compile (#2551) 2025-12-02 11:01:43 +01:00
Steven Palma
af4766b602 fix(ci): move hub artifacts to /mnt to avoid runners' No space left on device (#2564) 
* fix(ci): move hub & lerobot artefacts to /mnt to avoid No space left on device in the future

* chore(ci): remove dh -h steps
 2025-12-01 20:14:51 +01:00
Martino Russi
37f43df88a Feat/add unitree g1 robot (#2530) 
* add unitree_g1_robot_class

* finish locomotion loading code

* precommit

* separate groot locomotion logic

* remove leftover locomotion variable, unify kp kd

* format config

* properly comment config, example locomotion and unitree_g1 class

* ready to review

* download policy from the hub in `examples/unitree_g1/gr00t_locomotion`

* fix linter

* make precommit happy, add ignore flags

* linter pt3

* linter pt4

* [done] make precommit happy

* fix linter 5

* add docs

* push utils

* feat(robots): add Unitree G1 humanoid support with ZMQ bridge (#2539)

* feat(robots): add Unitree G1 humanoid support with ZMQ bridge

- Use JSON + base64 serialization for secure communication instead of pickle
- Add documentation section
- Rename robot_server to run_g1_server
- Add dependecies to pyproject.toml

* nit in docs

* remove globals use

* cast robot data to int/float

* ensure robot is connected before changing mode

* temperature can be list, average in such case

---------

Co-authored-by: Martino Russi <nopyeps@gmail.com>

* style nit

* remove transform_imu_data

* remove scipy dependency

* modify toml, add external unitree_sdk2py dep

* return actions from send_action

* cleaning

* add instructions for local deployment

* Update src/lerobot/robots/unitree_g1/unitree_g1.py

Co-authored-by: Copilot <175728472+Copilot@users.noreply.github.com>
Signed-off-by: Martino Russi <77496684+nepyope@users.noreply.github.com>

* update config and readme

* update docs

* update docs

* remove torch import

* fix docs

* remove ip from docs

* add licence header

---------

Signed-off-by: Martino Russi <77496684+nepyope@users.noreply.github.com>
Co-authored-by: Michel Aractingi <michel.aractingi@huggingface.co>
Co-authored-by: Copilot <175728472+Copilot@users.noreply.github.com>
 2025-12-01 16:10:13 +01:00
Sota Nakamura
5f7b5f2817 remove the sampler cause the relative index is added (#2521) 
Co-authored-by: Michel Aractingi <michel.aractingi@huggingface.co>
 2025-11-30 22:28:32 +01:00
Steven Palma
c55fbe1b3e chore(dependencies): Bump lerobot to 0.4.3 (#2540) 2025-11-28 10:39:02 +01:00
Steven Palma
58f70b6bd3 fix(scripts): better prints teleop (#2538) 2025-11-27 16:54:17 +01:00
Steven Palma
b07160eb1b feat(utils): precise_sleep() less CPU hungry without sacrificing accuracy (#2526) 2025-11-26 17:42:16 +01:00
Caroline Pascal
648ea8f485 fix(benchmark) : fixing video benchmark (#2094) 
* fix(time benchmark): removing deprecated TimeBenchmark dependency

* fix(typo): renaming frames in an up-to-date fashion

* feat(duets): rearanging crf and g parameters in a proper unique combination manner

* fix(segfault): fixing segfault by adding a lock in ThreadPoolExecutor

* chore(update) : update datasets, codecs and backends to the latest versions

* chore(unused files): removing unused files

* fix(dataset paths): fix datasets paths to live among lerobot datasets
 2025-11-26 17:41:31 +01:00
Caroline Pascal
581dd45eae feat(parallel encoding): making parallel encoding the default choice over all platforms (#2525) 2025-11-26 14:57:34 +01:00
Steven Palma
17581a9449 fix(examples): wrap all of them into a main function (#2524) 2025-11-26 14:28:04 +01:00
Steven Palma
87bee86640 feat(dataset): dynamic compress_level depending on the type of dataset (video or image) (#2517) 2025-11-25 19:11:12 +01:00
Steven Palma
18b32dced9 feat(dataset): speed-up encoding time (#2514) 
* feat(dataset): speed-up encoding time

* feat(dataset): add parallel encoding option

* feat(datasets): parallel encoding only if num_cams > 2

* feat(datasets): implement feedback
 2025-11-25 16:46:12 +01:00
Jade Choghari
36e8feefe3 docs: Add LeIsaac x LeRobot Envhub tutorial (#2498) 
* add leisaac doc

* depreciate il in sim

* fix readme

* more

* fix styling

* update title

* more changes

* more

* fix style

* more

* fix style
 2025-11-25 16:23:12 +01:00
135 changed files with 23976 additions and 2394 deletions
Expand all files Collapse all files

7
.github/workflows/fast_tests.yml vendored
View File

@@ -60,12 +60,19 @@ jobs:
runs-on: ubuntu-latest
env:
MUJOCO_GL: egl
HF_HOME: /mnt/cache/.cache/huggingface
HF_LEROBOT_HOME: /mnt/cache/.cache/huggingface/lerobot
steps:
- uses: actions/checkout@v4
with:
persist-credentials: false
lfs: true
# NOTE(Steven): Mount to `/mnt` to avoid the limited storage on `/home`. Consider cleaning default SDKs or using self-hosted runners for more space.
# (As of 2024-06-10, the runner's `/home` has only 6.2 GB free—8% of its 72 GB total.)
- name: Setup /mnt storage
run: sudo chown -R $USER:$USER /mnt
# TODO(Steven): Evaluate the need of these dependencies
- name: Install apt dependencies
run: |

7
.github/workflows/full_tests.yml vendored
View File

@@ -58,12 +58,19 @@ jobs:
github.event_name == 'workflow_dispatch'
env:
MUJOCO_GL: egl
HF_HOME: /mnt/cache/.cache/huggingface
HF_LEROBOT_HOME: /mnt/cache/.cache/huggingface/lerobot
steps:
- uses: actions/checkout@v4
with:
lfs: true
persist-credentials: false
# NOTE(Steven): Mount to `/mnt` to avoid the limited storage on `/home`. Consider cleaning default SDKs or using self-hosted runners for more space.
# (As of 2024-06-10, the runner's `/home` has only 6.2 GB free—8% of its 72 GB total.)
- name: Setup /mnt storage
run: sudo chown -R $USER:$USER /mnt
- name: Install apt dependencies
run: |
sudo apt-get update && sudo apt-get install -y build-essential \

7
.github/workflows/unbound_deps_tests.yml vendored
View File

@@ -45,12 +45,19 @@ jobs:
runs-on: ubuntu-latest
env:
MUJOCO_GL: egl
HF_HOME: /mnt/cache/.cache/huggingface
HF_LEROBOT_HOME: /mnt/cache/.cache/huggingface/lerobot
steps:
- uses: actions/checkout@v4
with:
lfs: true
persist-credentials: false
# NOTE(Steven): Mount to `/mnt` to avoid the limited storage on `/home`. Consider cleaning default SDKs or using self-hosted runners for more space.
# (As of 2024-06-10, the runner's `/home` has only 6.2 GB free—8% of its 72 GB total.)
- name: Setup /mnt storage
run: sudo chown -R $USER:$USER /mnt
- name: Install apt dependencies
run: |
sudo apt-get update && sudo apt-get install -y build-essential \

94
benchmarks/video/benchmark.py
View File

@@ -1,94 +0,0 @@
#!/usr/bin/env python
# Copyright 2024 The HuggingFace Inc. team. All rights reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
import threading
import time
from contextlib import ContextDecorator
class TimeBenchmark(ContextDecorator):
"""
Measures execution time using a context manager or decorator.
This class supports both context manager and decorator usage, and is thread-safe for multithreaded
environments.
Args:
print: If True, prints the elapsed time upon exiting the context or completing the function. Defaults
to False.
Examples:
Using as a context manager:
>>> benchmark = TimeBenchmark()
>>> with benchmark:
... time.sleep(1)
>>> print(f"Block took {benchmark.result:.4f} seconds")
Block took approximately 1.0000 seconds
Using with multithreading:
```python
import threading
benchmark = TimeBenchmark()
def context_manager_example():
with benchmark:
time.sleep(0.01)
print(f"Block took {benchmark.result_ms:.2f} milliseconds")
threads = []
for _ in range(3):
t1 = threading.Thread(target=context_manager_example)
threads.append(t1)
for t in threads:
t.start()
for t in threads:
t.join()
```
Expected output:
Block took approximately 10.00 milliseconds
Block took approximately 10.00 milliseconds
Block took approximately 10.00 milliseconds
"""
def __init__(self, print=False):
self.local = threading.local()
self.print_time = print
def __enter__(self):
self.local.start_time = time.perf_counter()
return self
def __exit__(self, *exc):
self.local.end_time = time.perf_counter()
self.local.elapsed_time = self.local.end_time - self.local.start_time
if self.print_time:
print(f"Elapsed time: {self.local.elapsed_time:.4f} seconds")
return False
@property
def result(self):
return getattr(self.local, "elapsed_time", None)
@property
def result_ms(self):
return self.result * 1e3

102
benchmarks/video/capture_camera_feed.py
View File

@@ -1,102 +0,0 @@
#!/usr/bin/env python
# Copyright 2024 The HuggingFace Inc. team. All rights reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
"""Capture video feed from a camera as raw images."""
import argparse
import datetime as dt
import os
import time
from pathlib import Path
import cv2
import rerun as rr
# see https://rerun.io/docs/howto/visualization/limit-ram
RERUN_MEMORY_LIMIT = os.getenv("LEROBOT_RERUN_MEMORY_LIMIT", "5%")
def display_and_save_video_stream(output_dir: Path, fps: int, width: int, height: int, duration: int):
rr.init("lerobot_capture_camera_feed")
rr.spawn(memory_limit=RERUN_MEMORY_LIMIT)
now = dt.datetime.now()
capture_dir = output_dir / f"{now:%Y-%m-%d}" / f"{now:%H-%M-%S}"
if not capture_dir.exists():
capture_dir.mkdir(parents=True, exist_ok=True)
# Opens the default webcam
cap = cv2.VideoCapture(0)
if not cap.isOpened():
print("Error: Could not open video stream.")
return
cap.set(cv2.CAP_PROP_FPS, fps)
cap.set(cv2.CAP_PROP_FRAME_WIDTH, width)
cap.set(cv2.CAP_PROP_FRAME_HEIGHT, height)
frame_index = 0
start_time = time.time()
while time.time() - start_time < duration:
ret, frame = cap.read()
if not ret:
print("Error: Could not read frame.")
break
rr.log("video/stream", rr.Image(frame), static=True)
cv2.imwrite(str(capture_dir / f"frame_{frame_index:06d}.png"), frame)
frame_index += 1
# Release the capture
cap.release()
# TODO(Steven): Add a graceful shutdown via a close() method for the Viewer context, though not currently supported in the Rerun API.
if __name__ == "__main__":
parser = argparse.ArgumentParser()
parser.add_argument(
"--output-dir",
type=Path,
default=Path("outputs/cam_capture/"),
help="Directory where the capture images are written. A subfolder named with the current date & time will be created inside it for each capture.",
)
parser.add_argument(
"--fps",
type=int,
default=30,
help="Frames Per Second of the capture.",
)
parser.add_argument(
"--width",
type=int,
default=1280,
help="Width of the captured images.",
)
parser.add_argument(
"--height",
type=int,
default=720,
help="Height of the captured images.",
)
parser.add_argument(
"--duration",
type=int,
default=20,
help="Duration in seconds for which the video stream should be captured.",
)
args = parser.parse_args()
display_and_save_video_stream(**vars(args))

61
benchmarks/video/run_video_benchmark.py
View File

@@ -21,11 +21,13 @@ See the provided README.md or run `python benchmark/video/run_video_benchmark.py
import argparse
import datetime as dt
import itertools
import random
import shutil
from collections import OrderedDict
from concurrent.futures import ThreadPoolExecutor, as_completed
from pathlib import Path
from threading import Lock
import einops
import numpy as np
@@ -35,13 +37,13 @@ import torch
from skimage.metrics import mean_squared_error, peak_signal_noise_ratio, structural_similarity
from tqdm import tqdm
from benchmarks.video.benchmark import TimeBenchmark
from lerobot.datasets.lerobot_dataset import LeRobotDataset
from lerobot.datasets.video_utils import (
decode_video_frames_torchvision,
decode_video_frames,
encode_video_frames,
)
from lerobot.utils.constants import OBS_IMAGE
from lerobot.utils.utils import TimerManager
BASE_ENCODING = OrderedDict(
[
@@ -86,7 +88,7 @@ def load_original_frames(imgs_dir: Path, timestamps: list[float], fps: int) -> t
frames = []
for ts in timestamps:
idx = int(ts * fps)
frame = PIL.Image.open(imgs_dir / f"frame_{idx:06d}.png")
frame = PIL.Image.open(imgs_dir / f"frame-{idx:06d}.png")
frame = torch.from_numpy(np.array(frame))
frame = frame.type(torch.float32) / 255
frame = einops.rearrange(frame, "h w c -> c h w")
@@ -97,21 +99,21 @@ def load_original_frames(imgs_dir: Path, timestamps: list[float], fps: int) -> t
def save_decoded_frames(
imgs_dir: Path, save_dir: Path, frames: torch.Tensor, timestamps: list[float], fps: int
) -> None:
if save_dir.exists() and len(list(save_dir.glob("frame_*.png"))) == len(timestamps):
if save_dir.exists() and len(list(save_dir.glob("frame-*.png"))) == len(timestamps):
return
save_dir.mkdir(parents=True, exist_ok=True)
for i, ts in enumerate(timestamps):
idx = int(ts * fps)
frame_hwc = (frames[i].permute((1, 2, 0)) * 255).type(torch.uint8).cpu().numpy()
PIL.Image.fromarray(frame_hwc).save(save_dir / f"frame_{idx:06d}_decoded.png")
shutil.copyfile(imgs_dir / f"frame_{idx:06d}.png", save_dir / f"frame_{idx:06d}_original.png")
PIL.Image.fromarray(frame_hwc).save(save_dir / f"frame-{idx:06d}_decoded.png")
shutil.copyfile(imgs_dir / f"frame-{idx:06d}.png", save_dir / f"frame-{idx:06d}_original.png")
def save_first_episode(imgs_dir: Path, dataset: LeRobotDataset) -> None:
episode_index = 0
ep_num_images = dataset.meta.episodes["length"][episode_index]
if imgs_dir.exists() and len(list(imgs_dir.glob("frame_*.png"))) == ep_num_images:
if imgs_dir.exists() and len(list(imgs_dir.glob("frame-*.png"))) == ep_num_images:
return
imgs_dir.mkdir(parents=True, exist_ok=True)
@@ -125,7 +127,7 @@ def save_first_episode(imgs_dir: Path, dataset: LeRobotDataset) -> None:
tqdm(imgs_dataset, desc=f"saving {dataset.repo_id} first episode images", leave=False)
):
img = item[img_keys[0]]
img.save(str(imgs_dir / f"frame_{i:06d}.png"), quality=100)
img.save(str(imgs_dir / f"frame-{i:06d}.png"), quality=100)
if i >= ep_num_images - 1:
break
@@ -149,18 +151,6 @@ def sample_timestamps(timestamps_mode: str, ep_num_images: int, fps: int) -> lis
return [idx / fps for idx in frame_indexes]
def decode_video_frames(
video_path: str,
timestamps: list[float],
tolerance_s: float,
backend: str,
) -> torch.Tensor:
if backend in ["pyav", "video_reader"]:
return decode_video_frames_torchvision(video_path, timestamps, tolerance_s, backend)
else:
raise NotImplementedError(backend)
def benchmark_decoding(
imgs_dir: Path,
video_path: Path,
@@ -172,8 +162,8 @@ def benchmark_decoding(
num_workers: int = 4,
save_frames: bool = False,
) -> dict:
def process_sample(sample: int):
time_benchmark = TimeBenchmark()
def process_sample(sample: int, lock: Lock):
time_benchmark = TimerManager(log=False)
timestamps = sample_timestamps(timestamps_mode, ep_num_images, fps)
num_frames = len(timestamps)
result = {
@@ -182,13 +172,13 @@ def benchmark_decoding(
"mse_values": [],
}
with time_benchmark:
with time_benchmark, lock:
frames = decode_video_frames(video_path, timestamps=timestamps, tolerance_s=5e-1, backend=backend)
result["load_time_video_ms"] = time_benchmark.result_ms / num_frames
result["load_time_video_ms"] = (time_benchmark.last * 1000) / num_frames
with time_benchmark:
original_frames = load_original_frames(imgs_dir, timestamps, fps)
result["load_time_images_ms"] = time_benchmark.result_ms / num_frames
result["load_time_images_ms"] = (time_benchmark.last * 1000) / num_frames
frames_np, original_frames_np = frames.numpy(), original_frames.numpy()
for i in range(num_frames):
@@ -215,8 +205,10 @@ def benchmark_decoding(
# A sample is a single set of decoded frames specified by timestamps_mode (e.g. a single frame, 2 frames, etc.).
# For each sample, we record metrics (loading time and quality metrics) which are then averaged over all samples.
# As these samples are independent, we run them in parallel threads to speed up the benchmark.
# Use a single shared lock for all worker threads
shared_lock = Lock()
with ThreadPoolExecutor(max_workers=num_workers) as executor:
futures = [executor.submit(process_sample, i) for i in range(num_samples)]
futures = [executor.submit(process_sample, i, shared_lock) for i in range(num_samples)]
for future in tqdm(as_completed(futures), total=num_samples, desc="samples", leave=False):
result = future.result()
load_times_video_ms.append(result["load_time_video_ms"])
@@ -358,11 +350,14 @@ def main(
imgs_dir = output_dir / "images" / dataset.repo_id.replace("/", "_")
# We only use the first episode
save_first_episode(imgs_dir, dataset)
for key, values in tqdm(encoding_benchmarks.items(), desc="encodings (g, crf)", leave=False):
for value in tqdm(values, desc=f"encodings ({key})", leave=False):
for duet in [
dict(zip(encoding_benchmarks.keys(), unique_combination, strict=False))
for unique_combination in itertools.product(*encoding_benchmarks.values())
]:
encoding_cfg = BASE_ENCODING.copy()
encoding_cfg["vcodec"] = video_codec
encoding_cfg["pix_fmt"] = pixel_format
for key, value in duet.items():
encoding_cfg[key] = value
args_path = Path("_".join(str(value) for value in encoding_cfg.values()))
video_path = output_dir / "videos" / args_path / f"{repo_id.replace('/', '_')}.mp4"
@@ -409,9 +404,9 @@ if __name__ == "__main__":
nargs="*",
default=[
"lerobot/pusht_image",
"aliberts/aloha_mobile_shrimp_image",
"aliberts/paris_street",
"aliberts/kitchen",
"lerobot/aloha_mobile_shrimp_image",
"lerobot/paris_street",
"lerobot/kitchen",
],
help="Datasets repo-ids to test against. First episodes only are used. Must be images.",
)
@@ -419,7 +414,7 @@ if __name__ == "__main__":
"--vcodec",
type=str,
nargs="*",
default=["libx264", "hevc", "libsvtav1"],
default=["h264", "hevc", "libsvtav1"],
help="Video codecs to be tested",
)
parser.add_argument(
@@ -468,7 +463,7 @@ if __name__ == "__main__":
"--backends",
type=str,
nargs="*",
default=["pyav", "video_reader"],
default=["torchcodec", "pyav"],
help="Torchvision decoding backend to be tested.",
)
parser.add_argument(

16
docs/source/_toctree.yml
View File

@@ -9,6 +9,8 @@
title: Imitation Learning for Robots
- local: cameras
title: Cameras
- local: bring_your_own_policies
title: Bring Your Own Policies
- local: integrate_hardware
title: Bring Your Own Hardware
- local: hilserl
@@ -37,6 +39,8 @@
title: π₀.₅ (Pi05)
- local: groot
title: NVIDIA GR00T N1.5
- local: xvla
title: X-VLA
title: "Policies"
- sections:
- local: async
@@ -47,8 +51,8 @@
- sections:
- local: envhub
title: Environments from the Hub
- local: il_sim
title: Imitation Learning in Sim
- local: envhub_leisaac
title: Control & Train Robots in Sim (LeIsaac)
- local: libero
title: Using Libero
- local: metaworld
@@ -79,11 +83,19 @@
title: Hope Jr
- local: reachy2
title: Reachy 2
- local: unitree_g1
title: Unitree G1
- local: earthrover_mini_plus
title: Earth Rover Mini
title: "Robots"
- sections:
- local: phone_teleop
title: Phone
title: "Teleoperators"
- sections:
- local: torch_accelerators
title: PyTorch accelerators
title: "Supported Hardware"
- sections:
- local: notebooks
title: Notebooks

6
docs/source/async.mdx
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@@ -196,7 +196,7 @@ client_cfg = RobotClientConfig(
server_address="localhost:8080",
policy_device="mps",
policy_type="smolvla",
pretrained_name_or_path="fracapuano/smolvla_async",
pretrained_name_or_path="<user>/smolvla_async",
chunk_size_threshold=0.5,
actions_per_chunk=50, # make sure this is less than the max actions of the policy
)
@@ -278,7 +278,7 @@ We found the default values of `actions_per_chunk` and `chunk_size_threshold` to
2. **Adjust your `fps` based on inference latency.** While the server generates a new action chunk, the client is not idle and is stepping through its current action queue. If the two processes happen at fundamentally different speeds, the client might end up with an empty queue. As such, you should reduce your fps if you consistently run out of actions in queue.
3. **Adjust `chunk_size_threshold`**.
- Values closer to `0.0` result in almost sequential behavior. Values closer to `1.0` → send observation every step (more bandwidth, relies on good world-model).
- We found values around 0.5-0.6 to work well. If you want to tweak this, spin up a `RobotClient` setting the `--debug-visualize-queue-size` to `True`. This will plot the action queue size evolution at runtime, and you can use it to find the value of `chunk_size_threshold` that works best for your setup.
- We found values around 0.5-0.6 to work well. If you want to tweak this, spin up a `RobotClient` setting the `--debug_visualize_queue_size` to `True`. This will plot the action queue size evolution at runtime, and you can use it to find the value of `chunk_size_threshold` that works best for your setup.
<p align="center">
<img
@@ -289,7 +289,7 @@ We found the default values of `actions_per_chunk` and `chunk_size_threshold` to
<p align="center">
<i>
The action queue size is plotted at runtime when the
`--debug-visualize-queue-size` flag is passed, for various levels of
`--debug_visualize_queue_size` flag is passed, for various levels of
`chunk_size_threshold` (`g` in the SmolVLA paper).
</i>
</p>

175
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@@ -0,0 +1,175 @@
# Bring Your Own Policies
This tutorial explains how to integrate your own custom policy implementations into the LeRobot ecosystem, allowing you to leverage all LeRobot tools for training, evaluation, and deployment while using your own algorithms.
## Step 1: Create a Policy Package
Your custom policy should be organized as an installable Python package following LeRobot's plugin conventions.
### Package Structure
Create a package with the prefix `lerobot_policy_` (IMPORTANT!) followed by your policy name:
```bash
lerobot_policy_my_custom_policy/
├── pyproject.toml
└── src/
└── lerobot_policy_my_custom_policy/
├── __init__.py
├── configuration_my_custom_policy.py
├── modeling_my_custom_policy.py
└── processor_my_custom_policy.py
```
### Package Configuration
Set up your `pyproject.toml`:
```toml
[project]
name = "lerobot_policy_my_custom_policy"
version = "0.1.0"
dependencies = [
# your policy-specific dependencies
]
requires-python = ">= 3.11"
[build-system]
build-backend = # your-build-backend
requires = # your-build-system
```
## Step 2: Define the Policy Configuration
Create a configuration class that inherits from `PreTrainedConfig` and registers your policy type:
```python
# configuration_my_custom_policy.py
from dataclasses import dataclass, field
from lerobot.configs.policies import PreTrainedConfig
from lerobot.configs.types import NormalizationMode
@PreTrainedConfig.register_subclass("my_custom_policy")
@dataclass
class MyCustomPolicyConfig(PreTrainedConfig):
"""Configuration class for MyCustomPolicy.
Args:
n_obs_steps: Number of observation steps to use as input
horizon: Action prediction horizon
n_action_steps: Number of action steps to execute
hidden_dim: Hidden dimension for the policy network
# Add your policy-specific parameters here
"""
# ...PreTrainedConfig fields...
pass
def __post_init__(self):
super().__post_init__()
# Add any validation logic here
def validate_features(self) -> None:
"""Validate input/output feature compatibility."""
# Implement validation logic for your policy's requirements
pass
```
## Step 3: Implement the Policy Class
Create your policy implementation by inheriting from LeRobot's base `PreTrainedPolicy` class:
```python
# modeling_my_custom_policy.py
import torch
import torch.nn as nn
from typing import Dict, Any
from lerobot.policies.pretrained import PreTrainedPolicy
from .configuration_my_custom_policy import MyCustomPolicyConfig
class MyCustomPolicy(PreTrainedPolicy):
config_class = MyCustomPolicyConfig
name = "my_custom_policy"
def __init__(self, config: MyCustomPolicyConfig, dataset_stats: Dict[str, Any] = None):
super().__init__(config, dataset_stats)
...
```
## Step 4: Add Data Processors
Create processor functions:
```python
# processor_my_custom_policy.py
from typing import Dict, Any
import torch
def make_my_custom_policy_pre_post_processors(
config,
) -> tuple[
PolicyProcessorPipeline[dict[str, Any], dict[str, Any]],
PolicyProcessorPipeline[PolicyAction, PolicyAction],
]:
"""Create preprocessing and postprocessing functions for your policy."""
pass # Define your preprocessing and postprocessing logic here
```
## Step 5: Package Initialization
Expose your classes in the package's `__init__.py`:
```python
# __init__.py
"""Custom policy package for LeRobot."""
try:
import lerobot # noqa: F401
except ImportError:
raise ImportError(
"lerobot is not installed. Please install lerobot to use this policy package."
)
from .configuration_my_custom_policy import MyCustomPolicyConfig
from .modeling_my_custom_policy import MyCustomPolicy
from .processor_my_custom_policy import make_my_custom_policy_pre_post_processors
__all__ = [
"MyCustomPolicyConfig",
"MyCustomPolicy",
"make_my_custom_policy_pre_post_processors",
]
```
## Step 6: Installation and Usage
### Install Your Policy Package
```bash
cd lerobot_policy_my_custom_policy
pip install -e .
# Or install from PyPI if published
pip install lerobot_policy_my_custom_policy
```
### Use Your Policy
Once installed, your policy automatically integrates with LeRobot's training and evaluation tools:
```bash
lerobot-train \
--policy.type my_custom_policy \
--env.type pusht \
--steps 200000
```
## Examples and Community Contributions
Check out these example policy implementations:
- [DiTFlow Policy](https://github.com/danielsanjosepro/lerobot_policy_ditflow) - Diffusion Transformer policy with flow-matching objective. Try it out in this example: [DiTFlow Example](https://github.com/danielsanjosepro/test_lerobot_policy_ditflow)
Share your policy implementations with the community! 🤗

206
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@@ -0,0 +1,206 @@
# EarthRover Mini Plus
The EarthRover Mini Plus is a fully open source mobile robot that connects through the cloud using the Frodobots SDK. This lets you control the robot and record datasets for training AI models.
## What You Need
### Hardware
- EarthRover Mini robot
- Computer with Python 3.10 or newer
- Internet connection
### Setting Up the Frodobots SDK
The robot needs the [Frodobots SDK](https://github.com/Frodobots/earth-rovers-sdk) running on your computer. Here's how:
1. Download and install the SDK:
```bash
git clone https://github.com/Frodobots/earth-rovers-sdk.git
cd earth-rovers-sdk
pip install -r requirements.txt
```
2. Start the SDK:
```bash
hypercorn main:app --reload
```
3. Open your web browser and go to `http://localhost:8000`, then click "Join"
The SDK gives you:
- Live video from front and rear cameras
> [!IMPORTANT]
> The SDK must be running before you can use the robot.
## Install LeRobot
Follow our [Installation Guide](./installation) to install LeRobot.
In addition to the base installation, install the EarthRover Mini dependencies:
```bash
pip install -e .
```
## How It Works
The robot uses the internet to communicate:
- **Movement commands**: Sent through the SDK
- **Camera video**: Received from the SDK
- **Robot info**: Battery, location, speed from the SDK
You don't need to plug anything in - it all works through the SDK.
## Calibration
No calibration needed! The robot is ready to use as soon as the SDK is running.
## Controlling the Robot
You control the robot using your keyboard - just like playing a video game with WASD keys.
### Keyboard Controls
| Key | Action |
| --- | -------------------------------- |
| W | Move forward |
| S | Move backward |
| A | Turn left (with forward motion) |
| D | Turn right (with forward motion) |
| Q | Rotate left in place |
| E | Rotate right in place |
| X | Stop all movement |
| +/= | Increase speed |
| - | Decrease speed |
| ESC | Disconnect |
### Speed Settings
You can adjust how fast the robot moves:
- **Forward/backward speed**: Default is full speed (1.0)
- **Turning speed**: Default is full speed (1.0)
- **Speed changes**: Use +/- keys to adjust by 0.1 each time
### Try It Out
Test driving the robot before recording data:
```python
from lerobot.robots.earthrover_mini_plus import EarthRoverMiniPlus, EarthRoverMiniPlusConfig
from lerobot.teleoperators.keyboard import KeyboardRoverTeleop, KeyboardRoverTeleopConfig
# Initialize robot
robot_config = EarthRoverMiniPlusConfig()
robot = EarthRoverMiniPlus(robot_config)
# Initialize teleoperator
teleop_config = KeyboardRoverTeleopConfig(
linear_speed=1.0,
angular_speed=1.0,
speed_increment=0.1
)
teleop = KeyboardRoverTeleop(teleop_config)
# Connect
robot.connect()
teleop.connect()
# Teleoperate (use keyboard controls)
try:
while True:
action = teleop.get_action()
robot.send_action(action)
except KeyboardInterrupt:
pass
finally:
robot.disconnect()
teleop.disconnect()
```
> [!TIP]
> If you're using a Mac, you might need to give Terminal permission to access your keyboard for teleoperation. Go to System Preferences > Security & Privacy > Input Monitoring and check the box for Terminal.
## Recording Data
Once you can drive the robot well, you can start recording data to train AI models. The system records:
- **What you do**: How you move the robot (forward, backward, turning)
- **What the robot sees**:
- Videos from both cameras
- Robot speed and direction
- Battery level and location
- GPS position and signal
- Other sensor data
- **When it happened**: Timestamps for everything
### Setting Up Hugging Face
We use Hugging Face to store your data online. First, log in with your token from [Hugging Face settings](https://huggingface.co/settings/tokens):
```bash
huggingface-cli login --token ${HUGGINGFACE_TOKEN} --add-to-git-credential
```
Store your Hugging Face username:
```bash
HF_USER=$(huggingface-cli whoami | head -n 1)
echo $HF_USER
```
### Start Recording
Use the standard recording command:
```bash
python src/lerobot/scripts/lerobot_record.py \
--robot.type=earthrover_mini_plus \
--teleop.type=keyboard_rover \
--dataset.repo_id=your_username/dataset_name \
--dataset.num_episodes=2 \
--dataset.fps=10 \
--dataset.single_task="Navigate around obstacles" \
--display_data=true
```
Replace `your_username/dataset_name` with your Hugging Face username and a name for your dataset.
### What Gets Saved
Your dataset includes:
**Your Actions (2 things)**:
- How much you moved forward/backward
- How much you turned left/right
**Robot Observations (12 things)**:
- Front camera video
- Rear camera video
- Current speed
- Battery level
- Which way the robot is facing
- GPS location (latitude, longitude, signal strength)
- Network signal strength
- Vibration level
- Lamp status (on/off)
### Where Your Data Goes
On your computer: `~/.cache/huggingface/lerobot/{repo-id}`
After recording, your data automatically uploads to your Hugging Face page:
```bash
echo https://huggingface.co/datasets/${HF_USER}/earthrover-navigation
```
Your dataset will be tagged with `LeRobot` for community discovery.

301
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@@ -0,0 +1,301 @@
# LeIsaac × LeRobot EnvHub
LeRobot EnvHub now supports **imitation learning in simulation** with LeIsaac.
Spin up everyday manipulation tasks, teleoperate the robot, collect demos, push them to the Hub, and train policies in LeRobot — all in one loop.
[LeIsaac](https://github.com/LightwheelAI/leisaac) integrates with IsaacLab and the SO101 Leader/Follower setup to provide:
- 🕹️ **Teleoperation-first workflows** for data collection
- 📦 **Built-in data conversion** ready for LeRobot training
- 🤖 **Everyday skills** like picking oranges, lifting cubes, cleaning tables, and folding cloth
- ☁️ **Ongoing upgrades** from [LightWheel](https://lightwheel.ai/): cloud simulation, EnvHub support, Sim2Real tooling, and more
Below youll find the currently supported LeIsaac tasks exposed through LeRobot EnvHub.
# Available Environments
The following table lists all available tasks and environments in LeIsaac x LeRobot Envhub. You can also get the latest list of environments by running the following command:
```bash
python scripts/environments/list_envs.py
```
| Task | Environment ID | Task Description | Related Robot |
| :-------------------------------------------------------------------------------------------------------------------------------------------------------------- | :-------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------- | :------------------------------------------------------------------------------------------------------------------------- | :--------------------------------------------------------- |
| <video src="https://github.com/user-attachments/assets/466eddff-f720-4f99-94d5-5e123e4c302c" autoplay loop muted playsinline style="max-width: 300px;"></video> | [LeIsaac-SO101-PickOrange-v0](https://github.com/LightwheelAI/leisaac/blob/main/source/leisaac/leisaac/tasks/pick_orange/pick_orange_env_cfg.py)<br /><br />[LeIsaac-SO101-PickOrange-Direct-v0](https://github.com/LightwheelAI/leisaac/blob/main/source/leisaac/leisaac/tasks/pick_orange/direct/pick_orange_env.py) | Pick three oranges and put them into the plate, then reset the arm to rest state. | Single-Arm SO101 Follower |
| <video src="https://github.com/user-attachments/assets/1e4eb83a-0b38-40fb-a0b2-ddb0fe201e6d" autoplay loop muted playsinline style="max-width: 300px;"></video> | [LeIsaac-SO101-LiftCube-v0](https://github.com/LightwheelAI/leisaac/blob/main/source/leisaac/leisaac/tasks/lift_cube/lift_cube_env_cfg.py)<br /><br />[LeIsaac-SO101-LiftCube-Direct-v0](https://github.com/LightwheelAI/leisaac/blob/main/source/leisaac/leisaac/tasks/lift_cube/direct/lift_cube_env.py) | Lift the red cube up. | Single-Arm SO101 Follower |
| <video src="https://github.com/user-attachments/assets/e49d8f1c-dcc9-412b-a88f-100680d8a45b" autoplay loop muted playsinline style="max-width: 300px;"></video> | [LeIsaac-SO101-CleanToyTable-v0](https://github.com/LightwheelAI/leisaac/blob/main/source/leisaac/leisaac/tasks/clean_toy_table/clean_toy_table_env_cfg.py)<br /><br />[LeIsaac-SO101-CleanToyTable-BiArm-v0](https://github.com/LightwheelAI/leisaac/blob/main/source/leisaac/leisaac/tasks/clean_toy_table/clean_toy_table_bi_arm_env_cfg.py)<br /><br />[LeIsaac-SO101-CleanToyTable-BiArm-Direct-v0](https://github.com/LightwheelAI/leisaac/blob/main/source/leisaac/leisaac/tasks/clean_toy_table/direct/clean_toy_table_bi_arm_env.py) | Pick two letter e objects into the box, and reset the arm to rest state. | Single-Arm SO101 Follower<br /><br />Bi-Arm SO101 Follower |
| <video src="https://github.com/user-attachments/assets/e29a0f8a-9286-4ce6-b45d-342c3d3ba754" autoplay loop muted playsinline style="max-width: 300px;"></video> | [LeIsaac-SO101-FoldCloth-BiArm-v0](https://github.com/LightwheelAI/leisaac/blob/main/source/leisaac/leisaac/tasks/fold_cloth/fold_cloth_bi_arm_env_cfg.py)<br /><br />[LeIsaac-SO101-FoldCloth-BiArm-Direct-v0](https://github.com/LightwheelAI/leisaac/blob/main/source/leisaac/leisaac/tasks/fold_cloth/direct/fold_cloth_bi_arm_env.py) | Fold the cloth, and reset the arm to rest state.<br /><br />_Note: Only the DirectEnv support check_success in this task._ | Bi-Arm SO101 Follower |
# Load LeIsaac directly in LeRobot with one line of code
> EnvHub: Share LeIsaac environments through HuggingFace
[EnvHub](https://huggingface.co/docs/lerobot/envhub) is our reproducible environment hub, spin up a packaged simulation with one line, experiment immediately, and publish your own tasks for the community.
LeIsaac offers EnvHub support so you can consume or share tasks with only a few commands.
<video
controls
src="https://github.com/user-attachments/assets/687666f5-ebe0-421d-84a0-eb86116ac5f8"
style={{ width: "100%", maxWidth: "960px", borderRadius: "8px" }}
/>
## How to get started, environment Setup
Run the following commands to setup your code environments:
```bash
# Refer to Getting Started/Installation to install leisaac firstly
conda create -n leisaac_envhub python=3.11
conda activate leisaac_envhub
conda install -c "nvidia/label/cuda-12.8.1" cuda-toolkit
pip install -U torch==2.7.0 torchvision==0.22.0 --index-url https://download.pytorch.org/whl/cu128
pip install 'leisaac[isaaclab] @ git+https://github.com/LightwheelAI/leisaac.git#subdirectory=source/leisaac' --extra-index-url https://pypi.nvidia.com
# Install lerobot
pip install lerobot==0.4.1
# Fix numpy version
pip install numpy==1.26.0
```
## Usage Example
EnvHub exposes every LeIsaac-supported task in a uniform interface. The examples below load `so101_pick_orange` and demonstrate a random-action rollout and an interactive teleoperation.
### Random Action
<details>
<summary>Click to expand code example</summary>
```python
# envhub_random_action.py
import torch
from lerobot.envs.factory import make_env
# Load from the hub
envs_dict = make_env("LightwheelAI/leisaac_env:envs/so101_pick_orange.py", n_envs=1, trust_remote_code=True)
# Access the environment
suite_name = next(iter(envs_dict))
sync_vector_env = envs_dict[suite_name][0]
# retrieve the isaac environment from the sync vector env
env = sync_vector_env.envs[0].unwrapped
# Use it like any gym environment
obs, info = env.reset()
while True:
action = torch.tensor(env.action_space.sample())
obs, reward, terminated, truncated, info = env.step(action)
if terminated or truncated:
obs, info = env.reset()
env.close()
```
</details>
```bash
python envhub_random_action.py
```
You should see the SO101 arm swinging under purely random commands.
### Teleoperation
LeRobots teleoperation stack can drive the simulated arm.
Connect the SO101 Leader controller, run the calibration command below.
```bash
lerobot-calibrate \
--teleop.type=so101_leader \
--teleop.port=/dev/ttyACM0 \
--teleop.id=leader
```
And then launch the teleop script.
<details>
<summary>Click to expand code example</summary>
```python
# envhub_teleop_example.py
import logging
import time
import gymnasium as gym
from dataclasses import asdict, dataclass
from pprint import pformat
from lerobot.teleoperators import ( # noqa: F401
Teleoperator,
TeleoperatorConfig,
make_teleoperator_from_config,
so101_leader,
)
from lerobot.utils.robot_utils import precise_sleep
from lerobot.utils.utils import init_logging
from lerobot.envs.factory import make_env
@dataclass
class TeleoperateConfig:
teleop: TeleoperatorConfig
env_name: str = "so101_pick_orange"
fps: int = 60
@dataclass
class EnvWrap:
env: gym.Env
def make_env_from_leisaac(env_name: str = "so101_pick_orange"):
envs_dict = make_env(
f'LightwheelAI/leisaac_env:envs/{env_name}.py',
n_envs=1,
trust_remote_code=True
)
suite_name = next(iter(envs_dict))
sync_vector_env = envs_dict[suite_name][0]
env = sync_vector_env.envs[0].unwrapped
return env
def teleop_loop(teleop: Teleoperator, env: gym.Env, fps: int):
from leisaac.devices.action_process import preprocess_device_action
from leisaac.assets.robots.lerobot import SO101_FOLLOWER_MOTOR_LIMITS
from leisaac.utils.env_utils import dynamic_reset_gripper_effort_limit_sim
env_wrap = EnvWrap(env=env)
obs, info = env.reset()
while True:
loop_start = time.perf_counter()
if env.cfg.dynamic_reset_gripper_effort_limit:
dynamic_reset_gripper_effort_limit_sim(env, 'so101leader')
raw_action = teleop.get_action()
processed_action = preprocess_device_action(
dict(
so101_leader=True,
joint_state={
k.removesuffix(".pos"): v for k, v in raw_action.items()},
motor_limits=SO101_FOLLOWER_MOTOR_LIMITS),
env_wrap
)
obs, reward, terminated, truncated, info = env.step(processed_action)
if terminated or truncated:
obs, info = env.reset()
dt_s = time.perf_counter() - loop_start
precise_sleep(1 / fps - dt_s)
loop_s = time.perf_counter() - loop_start
print(f"\ntime: {loop_s * 1e3:.2f}ms ({1 / loop_s:.0f} Hz)")
def teleoperate(cfg: TeleoperateConfig):
init_logging()
logging.info(pformat(asdict(cfg)))
teleop = make_teleoperator_from_config(cfg.teleop)
env = make_env_from_leisaac(cfg.env_name)
teleop.connect()
if hasattr(env, 'initialize'):
env.initialize()
try:
teleop_loop(teleop=teleop, env=env, fps=cfg.fps)
except KeyboardInterrupt:
pass
finally:
teleop.disconnect()
env.close()
def main():
teleoperate(TeleoperateConfig(
teleop=so101_leader.SO101LeaderConfig(
port="/dev/ttyACM0",
id='leader',
use_degrees=False,
),
env_name="so101_pick_orange",
fps=60,
))
if __name__ == "__main__":
main()
```
</details>
```bash
python envhub_teleop_example.py
```
Running the script lets you operate the simulated arm using the physical Leader device.
## ☁️ Cloud Simulation (No GPU Required)
Dont have a local GPU or the right drivers? No problem! You can run LeIsaac entirely in the cloud with zero setup.
LeIsaac works out-of-the-box on **NVIDIA Brev**, giving you a fully configured environment directly in your browser.
👉 **Start here:** [https://lightwheelai.github.io/leisaac/docs/cloud_simulation/nvidia_brev](https://lightwheelai.github.io/leisaac/docs/cloud_simulation/nvidia_brev)
Once your instance is deployed, simply open the link for **port 80 (HTTP)** to launch **Visual Studio Code Server** (default password: `password`). From there, you can run simulations, edit code, and visualize IsaacLab environments — all from your web browser.
**No GPU, no drivers, no local installation. Just click and run.**
## Additional Notes
We keep EnvHub coverage aligned with the LeIsaac task. Currently supported:
- `so101_pick_orange`
- `so101_lift_cube`
- `so101_clean_toytable`
- `bi_so101_fold_cloth`
Switch tasks by targeting a different script when calling `make_env`, for example:
```python
envs_dict_pick_orange = make_env("LightwheelAI/leisaac_env:envs/so101_pick_orange.py", n_envs=1, trust_remote_code=True)
envs_dict_lift_cube = make_env("LightwheelAI/leisaac_env:envs/so101_lift_cube.py", n_envs=1, trust_remote_code=True)
envs_dict_clean_toytable = make_env("LightwheelAI/leisaac_env:envs/so101_clean_toytable.py", n_envs=1, trust_remote_code=True)
envs_dict_fold_cloth = make_env("LightwheelAI/leisaac_env:envs/bi_so101_fold_cloth.py", n_envs=1, trust_remote_code=True)
```
Note: when working with `bi_so101_fold_cloth`, call `initialize()` immediately after retrieving the env before performing any other operations:
<details>
<summary>Click to expand code example</summary>
```python
import torch
from lerobot.envs.factory import make_env
# Load from the hub
envs_dict = make_env("LightwheelAI/leisaac_env:envs/bi_so101_fold_cloth.py", n_envs=1, trust_remote_code=True)
# Access the environment
suite_name = next(iter(envs_dict))
sync_vector_env = envs_dict[suite_name][0]
# retrieve the isaac environment from the sync vector env
env = sync_vector_env.envs[0].unwrapped
# NOTE: initialize() first
env.initialize()
# other operation with env...
```
</details>

8
docs/source/il_robots.mdx
View File

@@ -393,7 +393,7 @@ import time
from lerobot.datasets.lerobot_dataset import LeRobotDataset
from lerobot.robots.so100_follower.config_so100_follower import SO100FollowerConfig
from lerobot.robots.so100_follower.so100_follower import SO100Follower
from lerobot.utils.robot_utils import busy_wait
from lerobot.utils.robot_utils import precise_sleep
from lerobot.utils.utils import log_say
episode_idx = 0
@@ -415,7 +415,7 @@ for idx in range(dataset.num_frames):
}
robot.send_action(action)
busy_wait(1.0 / dataset.fps - (time.perf_counter() - t0))
precise_sleep(1.0 / dataset.fps - (time.perf_counter() - t0))
robot.disconnect()
```
@@ -428,7 +428,7 @@ Your robot should replicate movements similar to those you recorded. For example
## Train a policy
To train a policy to control your robot, use the [`lerobot-train`](https://github.com/huggingface/lerobot/blob/main/src/lerobot/scripts/train.py) script. A few arguments are required. Here is an example command:
To train a policy to control your robot, use the [`lerobot-train`](https://github.com/huggingface/lerobot/blob/main/src/lerobot/scripts/lerobot_train.py) script. A few arguments are required. Here is an example command:
```bash
lerobot-train \
@@ -485,7 +485,7 @@ huggingface-cli upload ${HF_USER}/act_so101_test${CKPT} \
## Run inference and evaluate your policy
You can use the `record` script from [`lerobot/record.py`](https://github.com/huggingface/lerobot/blob/main/src/lerobot/record.py) with a policy checkpoint as input, to run inference and evaluate your policy. For instance, run this command or API example to run inference and record 10 evaluation episodes:
You can use the `record` script from [`lerobot-record`](https://github.com/huggingface/lerobot/blob/main/src/lerobot/scripts/lerobot_record.py) with a policy checkpoint as input, to run inference and evaluate your policy. For instance, run this command or API example to run inference and record 10 evaluation episodes:
<hfoptions id="eval">
<hfoption id="Command">

220
docs/source/il_sim.mdx
View File

@@ -1,220 +0,0 @@
# Imitation Learning in Sim
This tutorial will explain how to train a neural network to control a robot in simulation with imitation learning.
**You'll learn:**
1. How to record a dataset in simulation with [gym-hil](https://github.com/huggingface/gym-hil) and visualize the dataset.
2. How to train a policy using your data.
3. How to evaluate your policy in simulation and visualize the results.
For the simulation environment we use the same [repo](https://github.com/huggingface/gym-hil) that is also being used by the Human-In-the-Loop (HIL) reinforcement learning algorithm.
This environment is based on [MuJoCo](https://mujoco.org) and allows you to record datasets in LeRobotDataset format.
Teleoperation is easiest with a controller like the Logitech F710, but you can also use your keyboard if you are up for the challenge.
## Installation
First, install the `gym_hil` package within the LeRobot environment, go to your LeRobot folder and run this command:
```bash
pip install -e ".[hilserl]"
```
## Teleoperate and Record a Dataset
To use `gym_hil` with LeRobot, you need to use a configuration file. An example config file can be found [here](https://huggingface.co/datasets/lerobot/config_examples/resolve/main/sim_il/env_config.json).
To teleoperate and collect a dataset, we need to modify this config file. Here's an example configuration for imitation learning data collection:
```json
{
"env": {
"type": "gym_manipulator",
"name": "gym_hil",
"task": "PandaPickCubeGamepad-v0",
"fps": 10
},
"dataset": {
"repo_id": "your_username/il_gym",
"root": null,
"task": "pick_cube",
"num_episodes_to_record": 30,
"replay_episode": null,
"push_to_hub": true
},
"mode": "record",
"device": "cuda"
}
```
Key configuration points:
- Set your `repo_id` in the `dataset` section: `"repo_id": "your_username/il_gym"`
- Set `num_episodes_to_record: 30` to collect 30 demonstration episodes
- Ensure `mode` is set to `"record"`
- If you don't have an NVIDIA GPU, change `"device": "cuda"` to `"mps"` for macOS or `"cpu"`
- To use keyboard instead of gamepad, change `"task"` to `"PandaPickCubeKeyboard-v0"`
Then we can run this command to start:
<hfoptions id="teleop_sim">
<hfoption id="Linux">
```bash
python -m lerobot.rl.gym_manipulator --config_path path/to/env_config_gym_hil_il.json
```
</hfoption>
<hfoption id="MacOS">
```bash
mjpython -m lerobot.rl.gym_manipulator --config_path path/to/env_config_gym_hil_il.json
```
</hfoption>
</hfoptions>
Once rendered you can teleoperate the robot with the gamepad or keyboard, below you can find the gamepad/keyboard controls.
Note that to teleoperate the robot you have to hold the "Human Take Over Pause Policy" Button `RB` to enable control!
**Gamepad Controls**
<p align="center">
<img
src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobot/gamepad_guide.jpg?raw=true"
alt="Figure shows the control mappings on a Logitech gamepad."
title="Gamepad Control Mapping"
width="100%"
></img>
</p>
<p align="center">
<i>Gamepad button mapping for robot control and episode management</i>
</p>
**Keyboard controls**
For keyboard controls use the `spacebar` to enable control and the following keys to move the robot:
```bash
Arrow keys: Move in X-Y plane
Shift and Shift_R: Move in Z axis
Right Ctrl and Left Ctrl: Open and close gripper
ESC: Exit
```
## Visualize a dataset
If you uploaded your dataset to the hub you can [visualize your dataset online](https://huggingface.co/spaces/lerobot/visualize_dataset) by copy pasting your repo id.
<p align="center">
<img
src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobot/dataset_visualizer_sim.png"
alt="Figure shows the dataset visualizer"
title="Dataset visualization"
width="100%"
></img>
</p>
<p align="center">
<i>Dataset visualizer</i>
</p>
## Train a policy
To train a policy to control your robot, use the [`lerobot-train`](https://github.com/huggingface/lerobot/blob/main/src/lerobot/scripts/train.py) script. A few arguments are required. Here is an example command:
```bash
lerobot-train \
--dataset.repo_id=${HF_USER}/il_gym \
--policy.type=act \
--output_dir=outputs/train/il_sim_test \
--job_name=il_sim_test \
--policy.device=cuda \
--wandb.enable=true
```
Let's explain the command:
1. We provided the dataset as argument with `--dataset.repo_id=${HF_USER}/il_gym`.
2. We provided the policy with `policy.type=act`. This loads configurations from [`configuration_act.py`](https://github.com/huggingface/lerobot/blob/main/src/lerobot/policies/act/configuration_act.py). Importantly, this policy will automatically adapt to the number of motor states, motor actions and cameras of your robot (e.g. `laptop` and `phone`) which have been saved in your dataset.
3. We provided `policy.device=cuda` since we are training on a Nvidia GPU, but you could use `policy.device=mps` to train on Apple silicon.
4. We provided `wandb.enable=true` to use [Weights and Biases](https://docs.wandb.ai/quickstart) for visualizing training plots. This is optional but if you use it, make sure you are logged in by running `wandb login`.
Training should take several hours, 100k steps (which is the default) will take about 1h on Nvidia A100. You will find checkpoints in `outputs/train/il_sim_test/checkpoints`.
#### Train using Collab
If your local computer doesn't have a powerful GPU you could utilize Google Collab to train your model by following the [ACT training notebook](./notebooks#training-act).
#### Upload policy checkpoints
Once training is done, upload the latest checkpoint with:
```bash
huggingface-cli upload ${HF_USER}/il_sim_test \
outputs/train/il_sim_test/checkpoints/last/pretrained_model
```
You can also upload intermediate checkpoints with:
```bash
CKPT=010000
huggingface-cli upload ${HF_USER}/il_sim_test${CKPT} \
outputs/train/il_sim_test/checkpoints/${CKPT}/pretrained_model
```
## Evaluate your policy in Sim
To evaluate your policy we have to use a configuration file. An example can be found [here](https://huggingface.co/datasets/lerobot/config_examples/resolve/main/sim_il/eval_config.json).
Here's an example evaluation configuration:
```json
{
"env": {
"type": "gym_manipulator",
"name": "gym_hil",
"task": "PandaPickCubeGamepad-v0",
"fps": 10
},
"dataset": {
"repo_id": "your_username/il_sim_dataset",
"dataset_root": null,
"task": "pick_cube"
},
"pretrained_policy_name_or_path": "your_username/il_sim_model",
"device": "cuda"
}
```
Make sure to replace:
- `repo_id` with the dataset you trained on (e.g., `your_username/il_sim_dataset`)
- `pretrained_policy_name_or_path` with your model ID (e.g., `your_username/il_sim_model`)
Then you can run this command to visualize your trained policy
<hfoptions id="eval_policy">
<hfoption id="Linux">
```bash
python -m lerobot.rl.eval_policy --config_path=path/to/eval_config_gym_hil.json
```
</hfoption>
<hfoption id="MacOS">
```bash
mjpython -m lerobot.rl.eval_policy --config_path=path/to/eval_config_gym_hil.json
```
</hfoption>
</hfoptions>
> [!WARNING]
> While the main workflow of training ACT in simulation is straightforward, there is significant room for exploring how to set up the task, define the initial state of the environment, and determine the type of data required during collection to learn the most effective policy. If your trained policy doesn't perform well, investigate the quality of the dataset it was trained on using our visualizers, as well as the action values and various hyperparameters related to ACT and the simulation.
Congrats 🎉, you have finished this tutorial. If you want to continue with using LeRobot in simulation follow this [Tutorial on reinforcement learning in sim with HIL-SERL](https://huggingface.co/docs/lerobot/hilserl_sim)
> [!TIP]
> If you have any questions or need help, please reach out on [Discord](https://discord.com/invite/s3KuuzsPFb).

2
docs/source/installation.mdx
View File

@@ -90,7 +90,7 @@ If you encounter build errors, you may need to install additional dependencies:
To install these for linux run:
```bash
sudo apt-get install cmake build-essential python-dev pkg-config libavformat-dev libavcodec-dev libavdevice-dev libavutil-dev libswscale-dev libswresample-dev libavfilter-dev pkg-config
sudo apt-get install cmake build-essential python3-dev pkg-config libavformat-dev libavcodec-dev libavdevice-dev libavutil-dev libswscale-dev libswresample-dev libavfilter-dev
```
For other systems, see: [Compiling PyAV](https://pyav.org/docs/develop/overview/installation.html#bring-your-own-ffmpeg)

5
docs/source/libero.mdx
View File

@@ -62,6 +62,11 @@ lerobot-eval \
- Pass a comma-separated list to `--env.task` for multi-suite evaluation.
### Control Mode
LIBERO now supports two control modes: relative and absolute. This matters because different VLA checkpoints are trained with different mode of action to output hence control parameterizations.
You can switch them with: `env.control_mode = "relative"` and `env.control_mode = "absolute"`
### Policy inputs and outputs
When using LIBERO through LeRobot, policies interact with the environment via **observations** and **actions**:

250
docs/source/so101.mdx
View File

@@ -30,131 +30,6 @@ The follower arm uses 6x STS3215 motors with 1/345 gearing. The leader, however,
| Wrist Roll | 5 | 1 / 147 |
| Gripper | 6 | 1 / 147 |
### Clean Parts
Remove all support material from the 3D-printed parts. The easiest way to do this is using a small screwdriver to get underneath the support material.
It is advisable to install one 3-pin cable in the motor after placing them before continuing assembly.
### Joint 1
- Place the first motor into the base.
- Fasten the motor with 4 M2x6mm screws (smallest screws). Two from the top and two from the bottom.
- Slide over the first motor holder and fasten it using two M2x6mm screws (one on each side).
- Install both motor horns, securing the top horn with a M3x6mm screw.
- Attach the shoulder part.
- Tighten the shoulder part with 4 M3x6mm screws on top and 4 M3x6mm screws on the bottom
- Add the shoulder motor holder.
<div class="video-container">
<video controls width="600">
<source
src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobot/Joint1_v2.mp4"
type="video/mp4"
/>
</video>
</div>
### Joint 2
- Slide the second motor in from the top.
- Fasten the second motor with 4 M2x6mm screws.
- Attach both motor horns to motor 2, again use the M3x6mm horn screw.
- Attach the upper arm with 4 M3x6mm screws on each side.
<div class="video-container">
<video controls width="600">
<source
src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobot/Joint2_v2.mp4"
type="video/mp4"
/>
</video>
</div>
### Joint 3
- Insert motor 3 and fasten using 4 M2x6mm screws
- Attach both motor horns to motor 3 and secure one again with a M3x6mm horn screw.
- Connect the forearm to motor 3 using 4 M3x6mm screws on each side.
<div class="video-container">
<video controls width="600">
<source
src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobot/Joint3_v2.mp4"
type="video/mp4"
/>
</video>
</div>
### Joint 4
- Slide over motor holder 4.
- Slide in motor 4.
- Fasten motor 4 with 4 M2x6mm screws and attach its motor horns, use a M3x6mm horn screw.
<div class="video-container">
<video controls width="600">
<source
src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobot/Joint4_v2.mp4"
type="video/mp4"
/>
</video>
</div>
### Joint 5
- Insert motor 5 into the wrist holder and secure it with 2 M2x6mm front screws.
- Install only one motor horn on the wrist motor and secure it with a M3x6mm horn screw.
- Secure the wrist to motor 4 using 4 M3x6mm screws on both sides.
<div class="video-container">
<video controls width="600">
<source
src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobot/Joint5_v2.mp4"
type="video/mp4"
/>
</video>
</div>
### Gripper / Handle
<hfoptions id="assembly">
<hfoption id="Follower">
- Attach the gripper to motor 5, attach it to the motor horn on the wrist using 4 M3x6mm screws.
- Insert the gripper motor and secure it with 2 M2x6mm screws on each side.
- Attach the motor horns and again use a M3x6mm horn screw.
- Install the gripper claw and secure it with 4 M3x6mm screws on both sides.
<div class="video-container">
<video controls width="600">
<source
src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobot/Gripper_v2.mp4"
type="video/mp4"
/>
</video>
</div>
</hfoption>
<hfoption id="Leader">
- Mount the leader holder onto the wrist and secure it with 4 M3x6mm screws.
- Attach the handle to motor 5 using 1 M2x6mm screw.
- Insert the gripper motor, secure it with 2 M2x6mm screws on each side, attach a motor horn using a M3x6mm horn screw.
- Attach the follower trigger with 4 M3x6mm screws.
<div class="video-container">
<video controls width="600">
<source
src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobot/Leader_v2.mp4"
type="video/mp4"
/>
</video>
</div>
</hfoption>
</hfoptions>
## Configure the motors
### 1. Find the USB ports associated with each arm
@@ -340,6 +215,131 @@ leader.setup_motors()
</hfoption>
</hfoptions>
### Clean Parts
Remove all support material from the 3D-printed parts. The easiest way to do this is using a small screwdriver to get underneath the support material.
It is advisable to install one 3-pin cable in the motor after placing them before continuing assembly.
### Joint 1
- Place the first motor into the base.
- Fasten the motor with 4 M2x6mm screws (smallest screws). Two from the top and two from the bottom.
- Slide over the first motor holder and fasten it using two M2x6mm screws (one on each side).
- Install both motor horns, securing the top horn with a M3x6mm screw.
- Attach the shoulder part.
- Tighten the shoulder part with 4 M3x6mm screws on top and 4 M3x6mm screws on the bottom
- Add the shoulder motor holder.
<div class="video-container">
<video controls width="600">
<source
src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobot/Joint1_v2.mp4"
type="video/mp4"
/>
</video>
</div>
### Joint 2
- Slide the second motor in from the top.
- Fasten the second motor with 4 M2x6mm screws.
- Attach both motor horns to motor 2, again use the M3x6mm horn screw.
- Attach the upper arm with 4 M3x6mm screws on each side.
<div class="video-container">
<video controls width="600">
<source
src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobot/Joint2_v2.mp4"
type="video/mp4"
/>
</video>
</div>
### Joint 3
- Insert motor 3 and fasten using 4 M2x6mm screws
- Attach both motor horns to motor 3 and secure one again with a M3x6mm horn screw.
- Connect the forearm to motor 3 using 4 M3x6mm screws on each side.
<div class="video-container">
<video controls width="600">
<source
src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobot/Joint3_v2.mp4"
type="video/mp4"
/>
</video>
</div>
### Joint 4
- Slide over motor holder 4.
- Slide in motor 4.
- Fasten motor 4 with 4 M2x6mm screws and attach its motor horns, use a M3x6mm horn screw.
<div class="video-container">
<video controls width="600">
<source
src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobot/Joint4_v2.mp4"
type="video/mp4"
/>
</video>
</div>
### Joint 5
- Insert motor 5 into the wrist holder and secure it with 2 M2x6mm front screws.
- Install only one motor horn on the wrist motor and secure it with a M3x6mm horn screw.
- Secure the wrist to motor 4 using 4 M3x6mm screws on both sides.
<div class="video-container">
<video controls width="600">
<source
src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobot/Joint5_v2.mp4"
type="video/mp4"
/>
</video>
</div>
### Gripper / Handle
<hfoptions id="assembly">
<hfoption id="Follower">
- Attach the gripper to motor 5, attach it to the motor horn on the wrist using 4 M3x6mm screws.
- Insert the gripper motor and secure it with 2 M2x6mm screws on each side.
- Attach the motor horns and again use a M3x6mm horn screw.
- Install the gripper claw and secure it with 4 M3x6mm screws on both sides.
<div class="video-container">
<video controls width="600">
<source
src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobot/Gripper_v2.mp4"
type="video/mp4"
/>
</video>
</div>
</hfoption>
<hfoption id="Leader">
- Mount the leader holder onto the wrist and secure it with 4 M3x6mm screws.
- Attach the handle to motor 5 using 1 M2x6mm screw.
- Insert the gripper motor, secure it with 2 M2x6mm screws on each side, attach a motor horn using a M3x6mm horn screw.
- Attach the follower trigger with 4 M3x6mm screws.
<div class="video-container">
<video controls width="600">
<source
src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobot/Leader_v2.mp4"
type="video/mp4"
/>
</video>
</div>
</hfoption>
</hfoptions>
## Calibrate
Next, you'll need to calibrate your robot to ensure that the leader and follower arms have the same position values when they are in the same physical position.

42
docs/source/torch_accelerators.mdx Normal file
View File

@@ -0,0 +1,42 @@
# PyTorch accelerators
LeRobot supports multiple hardware acceleration options for both training and inference.
These options include:
- **CPU**: CPU executes all computations, no dedicated accelerator is used
- **CUDA**: acceleration with NVIDIA & AMD GPUs
- **MPS**: acceleration with Apple Silicon GPUs
- **XPU**: acceleration with Intel integrated and discrete GPUs
## Getting Started
To use particular accelerator, a suitable version of PyTorch should be installed.
For CPU, CUDA, and MPS backends follow instructions provided on [PyTorch installation page](https://pytorch.org/get-started/locally).
For XPU backend, follow instructions from [PyTorch documentation](https://docs.pytorch.org/docs/stable/notes/get_start_xpu.html).
### Verifying the installation
After installation, accelerator availability can be verified by running
```python
import torch
print(torch.<backend_name>.is_available()) # <backend_name> is cuda, mps, or xpu
```
## How to run training or evaluation
To select the desired accelerator, use the `--policy.device` flag when running `lerobot-train` or `lerobot-eval`. For example, to use MPS on Apple Silicon, run:
```bash
lerobot-train
--policy.device=mps ...
```
```bash
lerobot-eval \
--policy.device=mps ...
```
However, in most cases, presence of an accelerator is detected automatically and `policy.device` parameter can be omitted from CLI commands.

203
docs/source/unitree_g1.mdx Normal file
View File

@@ -0,0 +1,203 @@
# Unitree G1 Robot Setup and Control
This guide covers the complete setup process for the Unitree G1 humanoid, from initial connection to running gr00t_wbc locomotion.
## About the Unitree G1
We offer support for both 29 and 23 DOF G1. In this first PR we introduce:
- **`unitree g1` robot class, handling low level communication with the humanoid**
- **ZMQ socket bridge** for remote communication over WiFi, allowing one to deploy policies remotely instead of over ethernet or directly on the Orin
- **GR00T locomotion policy** for bipedal walking and balance
---
## Part 1: Connect to Robot over Ethernet
### Step 1: Configure Your Computer's Ethernet Interface
Set a static IP on the same subnet as the robot:
```bash
# Replace 'enp131s0' with your ethernet interface name (check with `ip a`)
sudo ip addr flush dev enp131s0
sudo ip addr add 192.168.123.200/24 dev enp131s0
sudo ip link set enp131s0 up
```
**Note**: The robot's Ethernet IP is fixed at `192.168.123.164`. Your computer must use `192.168.123.x` where x ≠ 164.
### Step 2: SSH into the Robot
```bash
ssh unitree@192.168.123.164
# Password: 123
```
You should now be connected to the robot's onboard computer.
---
## Part 2: Enable WiFi on the Robot
Once connected via Ethernet, follow these steps to enable WiFi:
### Step 1: Enable WiFi Hardware
```bash
# Unblock WiFi radio
sudo rfkill unblock wifi
sudo rfkill unblock all
# Bring up WiFi interface
sudo ip link set wlan0 up
# Enable NetworkManager control
sudo nmcli radio wifi on
sudo nmcli device set wlan0 managed yes
sudo systemctl restart NetworkManager
```
### Step 2: Enable Internet Forwarding
**On your laptop:**
```bash
# Enable IP forwarding
sudo sysctl -w net.ipv4.ip_forward=1
# Set up NAT (replace wlp132s0f0 with your WiFi interface)
sudo iptables -t nat -A POSTROUTING -o wlp132s0f0 -s 192.168.123.0/24 -j MASQUERADE
sudo iptables -A FORWARD -i wlp132s0f0 -o enp131s0 -m state --state RELATED,ESTABLISHED -j ACCEPT
sudo iptables -A FORWARD -i enp131s0 -o wlp132s0f0 -j ACCEPT
```
**On the robot:**
```bash
# Add laptop as default gateway
sudo ip route del default 2>/dev/null || true
sudo ip route add default via 192.168.123.200 dev eth0
echo "nameserver 8.8.8.8" | sudo tee /etc/resolv.conf
# Test connection
ping -c 3 8.8.8.8
```
### Step 3: Connect to WiFi Network
```bash
# List available networks
nmcli device wifi list
# Connect to your WiFi (example)
sudo nmcli connection add type wifi ifname wlan0 con-name "YourNetwork" ssid "YourNetwork"
sudo nmcli connection modify "YourNetwork" wifi-sec.key-mgmt wpa-psk
sudo nmcli connection modify "YourNetwork" wifi-sec.psk "YourPassword"
sudo nmcli connection modify "YourNetwork" connection.autoconnect yes
sudo nmcli connection up "YourNetwork"
# Check WiFi IP address
ip a show wlan0
```
### Step 4: SSH Over WiFi
Once connected to WiFi, note the robot's IP address and disconnect the Ethernet cable. You can now SSH over WiFi:
```bash
ssh unitree@<YOUR_ROBOT_IP>
# Password: 123
```
Replace `<YOUR_ROBOT_IP>` with your robot's actual WiFi IP address (e.g., `172.18.129.215`).
---
## Part 3: Robot Server Setup
### Step 1: Install LeRobot on the Orin
SSH into the robot and install LeRobot:
```bash
ssh unitree@<YOUR_ROBOT_IP>
conda create -y -n lerobot python=3.10
conda activate lerobot
git clone https://github.com/huggingface/lerobot.git
cd lerobot
pip install -e '.[unitree_g1]'
git clone https://github.com/unitreerobotics/unitree_sdk2_python.git
cd unitree_sdk2_python && pip install -e .
```
**Note**: The Unitree SDK requires CycloneDDS v0.10.2 to be installed. See the [Unitree SDK documentation](https://github.com/unitreerobotics/unitree_sdk2_python) for details.
### Step 2: Run the Robot Server
On the robot:
```bash
python src/lerobot/robots/unitree_g1/run_g1_server.py
```
**Important**: Keep this terminal running. The server must be active for remote control.
---
## Part 4: Running GR00T Locomotion
With the robot server running, you can now control the robot from your laptop.
### Step 1: Install LeRobot on your machine
```bash
conda create -y -n lerobot python=3.10
conda activate lerobot
git clone https://github.com/huggingface/lerobot.git
cd lerobot
pip install -e '.[unitree_g1]'
git clone https://github.com/unitreerobotics/unitree_sdk2_python.git
cd unitree_sdk2_python && pip install -e .
```
### Step 2: Update Robot IP in Config
Edit the config file to match your robot's WiFi IP:
```python
# In src/lerobot/robots/unitree_g1/config_unitree_g1.py
robot_ip: str = "<YOUR_ROBOT_IP>" # Replace with your robot's WiFi IP.
```
**Note**: When running directly on the G1 (not remotely), set `robot_ip: str = "127.0.0.1"` instead.
### Step 3: Run the Locomotion Policy
```bash
# Run GR00T locomotion controller
python examples/unitree_g1/gr00t_locomotion.py --repo-id "nepyope/GR00T-WholeBodyControl_g1"
```
### Step 4: Control with Remote
- **Left stick**: Forward/backward and left/right movement
- **Right stick**: Rotation
- **R1 button**: Raise waist height
- **R2 button**: Lower waist height
Press `Ctrl+C` to stop the policy.
---
## Additional Resources
- [Unitree SDK Documentation](https://github.com/unitreerobotics/unitree_sdk2_python)
- [GR00T Policy Repository](https://huggingface.co/nepyope/GR00T-WholeBodyControl_g1)
- [LeRobot Documentation](https://github.com/huggingface/lerobot)
- [Unitree_IL_Lerobot](https://github.com/unitreerobotics/unitree_IL_lerobot)
---
_Last updated: December 2025_

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# X-VLA: The First Soft-Prompted Robot Foundation Model for Any Robot, Any Task
## Overview
For years, robotics has aspired to build agents that can follow natural human instructions and operate dexterously across many environments and robot bodies. Recent breakthroughs in LLMs and VLMs suggest a path forward: extend these foundation-model architectures to embodied control by grounding them in actions. This has led to the rise of Vision-Language-Action (VLA) models, with the hope that a single generalist model could combine broad semantic understanding with robust manipulation skills.
But training such models is difficult. Robot data is fragmented across platforms, sensors, embodiments, and collection protocols. Heterogeneity appears everywhere: different arm configurations, different action spaces, different camera setups, different visual domains, and different task distributions. These inconsistencies create major distribution shifts that make pretraining unstable and adaptation unreliable.
Inspired by meta-learning and prompt learning, we ask: **"What if a VLA model could learn the structure of each robot and dataset the same way LLMs learn tasks, through prompts?"**
**X-VLA** is a soft-prompted, flow-matching VLA framework that treats each hardware setup as a "task" and encodes it using a small set of learnable embeddings. These **Soft Prompts** capture embodiment and domain-specific variations, guiding the Transformer from the earliest stages of multimodal fusion. With this mechanism, X-VLA can reconcile diverse robot morphologies, data types, and sensor setups within a single unified architecture.
<p align="center">
<img
src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobot/xvla-architecture.png"
alt="XVLA Architecture"
style="max-width: 100%; height: auto; width: 800px;"
/>
</p>
Built from pure Transformer encoders, X-VLA scales naturally with model size and dataset diversity. Across 6 simulation benchmarks and 3 real robots, Soft Prompts consistently outperform existing methods in handling hardware and domain differences. X-VLA-0.9B, trained on 290K episodes spanning seven robotic platforms, learns an embodiment-agnostic generalist policy in Phase I, and adapts efficiently to new robots in Phase II simply by learning a new set of prompts, while keeping the backbone frozen.
<p align="center">
<img
src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobot/xvla-architecture2.png"
alt="XVLA Architecture 2"
style="width: 32%; max-width: 450px; height: auto;"
/>
</p>
With only 1% of parameters tuned (9M), X-VLA-0.9B achieves near-π₀ performance on LIBERO and Simpler-WidowX, despite using **300× fewer trainable parameters**. It also demonstrates strong real-world dexterity with minimal demonstrations, including folding cloths in under two minutes.
<p align="center">
<img
src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobot/xvla-fold.png"
alt="XVLA fold visualization"
style="width: 95%; max-width: 1100px; height: auto;"
/>
</p>
X-VLA shows that generalist robot intelligence does not require increasingly complex architectures, only the right way to absorb heterogeneity. Soft Prompts offer a simple, scalable mechanism for unifying diverse robotic data, paving the way toward adaptable, cross-embodiment robot foundation models.
## Installation
After installing LeRobot, install the X-VLA dependencies:
```bash
pip install -e .[xvla]
```
After the new release, you'll be able to do:
```bash
pip install lerobot[xvla]
```
## Quick Start
### Basic Usage
To use X-VLA in your LeRobot configuration, specify the policy type as:
```bash
policy.type=xvla
```
### Evaluating Pre-trained Checkpoints
Example evaluation with LIBERO:
```bash
lerobot-eval \
--policy.path="lerobot/xvla-libero" \
--env.type=libero \
--env.task=libero_spatial,libero_goal,libero_10 \
--env.control_mode=absolute \
--eval.batch_size=1 \
--eval.n_episodes=1 \
--env.episode_length=800 \
--seed=142
```
## Available Checkpoints
### 🎯 Base Model
**[lerobot/xvla-base](https://huggingface.co/lerobot/xvla-base)**
A 0.9B parameter instantiation of X-VLA, trained with a carefully designed data processing and learning recipe. The training pipeline consists of two phases:
- **Phase I: Pretraining** - Pretrained on 290K episodes from Droid, Robomind, and Agibot, spanning seven platforms across five types of robotic arms (single-arm to bi-manual setups). By leveraging soft prompts to absorb embodiment-specific variations, the model learns an embodiment-agnostic generalist policy.
- **Phase II: Domain Adaptation** - Adapted to deployable policies for target domains. A new set of soft prompts is introduced and optimized to encode the hardware configuration of the novel domain, while the pretrained backbone remains frozen.
### Simulation Checkpoints
**[lerobot/xvla-libero](https://huggingface.co/lerobot/xvla-libero)**
Achieves 93% success rate on LIBERO benchmarks. Fine-tuned from the base model for simulation tasks.
**[lerobot/xvla-widowx](https://huggingface.co/lerobot/xvla-widowx)**
Fine-tuned on BridgeData for pick-and-place experiments on compact WidowX platforms. Demonstrates robust manipulation capabilities.
### 🤖 Real-World Checkpoints
**[lerobot/xvla-folding](https://huggingface.co/lerobot/xvla-folding)**
A fine-tuned dexterous manipulation model trained on the high-quality Soft-FOLD cloth folding dataset. Achieves 100% success rate over 2 hours of continuous cloth folding.
**[lerobot/xvla-agibot-world](https://huggingface.co/lerobot/xvla-agibot-world)**
Optimized for AgileX robot dexterous manipulation tasks.
**[lerobot/xvla-google-robot](https://huggingface.co/lerobot/xvla-google-robot)**
Adapted for Google Robot platforms.
## Training X-VLA
### Recommended Training Configuration
When fine-tuning X-VLA for a new embodiment or task, we recommend the following freezing strategy:
```bash
lerobot-train \
--dataset.repo_id=YOUR_DATASET \
--output_dir=./outputs/xvla_training \
--job_name=xvla_training \
--policy.path="lerobot/xvla-base" \
--policy.repo_id="HF_USER/xvla-your-robot" \
--steps=3000 \
--policy.device=cuda \
--policy.freeze_vision_encoder=True \
--policy.freeze_language_encoder=True \
--policy.train_policy_transformer=True \
--policy.train_soft_prompts=True \
--policy.action_mode=YOUR_ACTION_MODE
```
### Training Parameters Explained
| Parameter | Default | Description |
| -------------------------- | ------- | ---------------------------------------- |
| `freeze_vision_encoder` | `True` | Freeze the VLM vision encoder weights |
| `freeze_language_encoder` | `True` | Freeze the VLM language encoder weights |
| `train_policy_transformer` | `True` | Allow policy transformer layers to train |
| `train_soft_prompts` | `True` | Allow soft prompts to train |
**💡 Best Practice**: For Phase II adaptation to new embodiments, freeze the VLM encoders and only train the policy transformer and soft prompts. This provides excellent sample efficiency with minimal compute.
### Example: Training on Bimanual Robot
```bash
lerobot-train \
--dataset.repo_id=pepijn223/bimanual-so100-handover-cube \
--output_dir=./outputs/xvla_bimanual \
--job_name=xvla_so101_training \
--policy.path="lerobot/xvla-base" \
--policy.repo_id="YOUR_USERNAME/xvla-biso101" \
--steps=3000 \
--policy.device=cuda \
--policy.action_mode=so101_bimanual \
--policy.freeze_vision_encoder=True \
--policy.freeze_language_encoder=True \
--policy.train_policy_transformer=True \
--policy.train_soft_prompts=True
```
💡 **Best Performance:** If you have sufficient computational resources and want to achieve best X-VLA finetuning performance, you should follow the official finetuning strategy:
**🔥 Full-finetune all components with a custom learning-rate scheme**
To ensure stable optimization, the Vision-Language Model (VLM) must be trained with only 1/10 of the base learning rate, while all other components use the full LR.
This LR ratio is crucial for achieving strong and stable finetuning performance.
To enable this behavior, you must:
1. Implement a custom optimizer and register it in your training config
```
from dataclasses import dataclass, asdict
from lerobot.optim.optimizers import OptimizerConfig
import torch
@OptimizerConfig.register_subclass("xvla-adamw")
@dataclass
class XVLAAdamW(OptimizerConfig):
lr: float = 1e-4
betas: tuple[float, float] = (0.9, 0.99)
eps: float = 1e-8
weight_decay: float = 0.0
grad_clip_norm: float = 10.0
def build(self, params: dict) -> torch.optim.Optimizer:
"""
Expect `named_parameters()` as input.
Apply lr = lr / 10 for all VLM-related parameters.
"""
assert isinstance(params, dict), \
"Custom LR optimizer requires `named_parameters()` as inputs."
kwargs = asdict(self)
kwargs.pop("grad_clip_norm")
vlm_group, other_group = [], []
for name, p in params.items():
if not p.requires_grad:
continue
if "vlm" in name.lower():
vlm_group.append(p)
else:
other_group.append(p)
param_groups = [
{"params": vlm_group, "lr": self.lr * 0.1, "weight_decay": self.weight_decay * 0.1},
{"params": other_group, "lr": self.lr, "weight_decay": self.weight_decay},
]
return torch.optim.AdamW(param_groups, **kwargs)
```
2. Modify X-VLAs get_optim_params to return named parameters
Replace:
```
def get_optim_params(self) -> dict:
"""Return only trainable parameters for optimization."""
return filter(lambda p: p.requires_grad, self.parameters())
```
with:
```
def get_optim_params(self):
"""Return trainable named parameters."""
return filter(lambda kv: kv[1].requires_grad, self.named_parameters())
```
This ensures the optimizer receives a dict of named parameters, allowing it to correctly detect VLM modules and apply the 1/10 LR rule.
❕Note
Completely matching the official reported performance may require an additional warm-up LR schedule for soft-prompts, which can bring minor improvements.
We encourage implementing this in your customized training pipeline for optimal results.
## Core Concepts
### 1. Action Modes
X-VLA uses an **Action Registry** system to handle different action spaces and embodiments. The `action_mode` parameter defines how actions are processed, what loss functions are used, and how predictions are post-processed.
#### Available Action Modes
| Action Mode | Action Dim | Description | Use Case |
| ---------------- | ----------------------- | ------------------------------------------- | ------------------------------------ |
| `ee6d` | 20 | End-effector with xyz, 6D rotation, gripper | Dual-arm setups with spatial control |
| `joint` | 14 | Joint-space with gripper | Direct joint control robots |
| `agibot_ee6d` | 20 | AGI-bot variant with MSE loss | AGI-bot platforms |
| `so101_bimanual` | 20 (model), 12 (real) | SO101 bimanual robot | Bimanual manipulation tasks |
| `auto` | 20 (model), auto (real) | Auto-detects action dim from dataset | **Recommended** for new robots |
#### Why Action Modes Matter
When you have a pretrained checkpoint like `lerobot/xvla-base` trained with `action_dim=20`, and you want to train on a dataset with a different action dimension (e.g., 14 for bimanual arms), you can't simply trim the action dimension. The action mode orchestrates:
1. **Loss Computation**: Different loss functions for different action components (MSE for joints, BCE for grippers, etc.)
2. **Preprocessing**: Zeroing out gripper channels, padding dimensions
3. **Postprocessing**: Applying sigmoid to gripper logits, trimming padding
#### Example: BimanualSO101 Action Space
The `so101_bimanual` action mode handles the mismatch between model output (20D) and real robot control (12D):
```python
# Model outputs 20 dimensions for compatibility
dim_action = 20
# Real robot only needs 12 dimensions
# [left_arm (6), right_arm (6)] = [joints (5) + gripper (1)] × 2
REAL_DIM = 12
# Preprocessing: Pad 12D actions to 20D for training
# Postprocessing: Trim 20D predictions to 12D for deployment
```
See the [action_hub.py](/home/jade_choghari/robot/lerobot/src/lerobot/policies/xvla/action_hub.py) implementation for details.
#### Auto Action Mode (Recommended)
The `auto` action mode is the easiest way to use X-VLA with any robot. It automatically detects your dataset's action dimension and handles padding/trimming:
```bash
lerobot-train \
--policy.path="lerobot/xvla-base" \
--policy.action_mode=auto \
--policy.max_action_dim=20 \
...
```
**How it works:**
- Reads `action_feature.shape[-1]` from your dataset (e.g., 7 for Franka)
- Model outputs `max_action_dim` (default 20) for pretrained compatibility
- Loss is computed **only on the real dimensions**: `MSE(pred[:,:,:real_dim], target[:,:,:real_dim])`
- Postprocess trims output back to `real_dim` for robot control
This eliminates the need to create custom action modes for most robots.
### 2. Domain IDs
Domain IDs are learnable identifiers for different robot configurations and camera setups. They allow X-VLA to distinguish between:
- Different robots (Robot 1 vs Robot 2)
- Different camera configurations (cam1 vs cam2)
- Different combinations (Robot1-cam1-cam2 vs Robot1-cam1 vs Robot2-cam1)
#### Setting Domain IDs
**During Training**: By default, domain_id is set to 0 for general training.
**During Evaluation**: Specify the domain_id that matches your checkpoint's training configuration.
```python
# Example: LIBERO checkpoint uses domain_id=3
domain_id = 3
```
The domain_id is automatically added to observations by the `XVLAAddDomainIdProcessorStep` in the preprocessing pipeline.
### 3. Processor Steps
X-VLA requires specific preprocessing and postprocessing steps for proper operation.
#### Required Preprocessing Steps
1. **XVLAImageToFloatProcessorStep**: Converts images from [0, 255] to [0, 1] range
2. **XVLAImageNetNormalizeProcessorStep**: Applies ImageNet normalization (required for VLM backbone)
3. **XVLAAddDomainIdProcessorStep**: Adds domain_id to observations
#### Example Custom Processor
For LIBERO environments, a custom processor handles the specific observation format:
```python
from lerobot.policies.xvla.processor_xvla import LiberoProcessorStep
processor = LiberoProcessorStep()
# Handles robot_state dictionary, converts rotation matrices to 6D representation
# Applies 180° image rotation for camera convention
```
### 4. Configuration Parameters
Key configuration parameters for X-VLA:
```python
# Observation and action
n_obs_steps: int = 1 # Number of observation timesteps
chunk_size: int = 32 # Action sequence length
n_action_steps: int = 32 # Number of action steps to execute
# Model architecture
hidden_size: int = 1024 # Transformer hidden dimension
depth: int = 24 # Number of transformer layers
num_heads: int = 16 # Number of attention heads
num_domains: int = 30 # Maximum number of domain IDs
len_soft_prompts: int = 32 # Length of soft prompt embeddings
# Action space
action_mode: str = "ee6d" # Action space type (use "auto" for auto-detection)
use_proprio: bool = True # Use proprioceptive state
max_state_dim: int = 32 # Maximum state dimension
max_action_dim: int = 20 # Max action dim for padding (used by "auto" mode)
# Vision
num_image_views: int | None # Number of camera views
resize_imgs_with_padding: tuple[int, int] | None # Target image size with padding
# Training
num_denoising_steps: int = 10 # Flow matching denoising steps
```
## Creating Custom Action Modes
If your robot has a unique action space, you can create a custom action mode:
### Step 1: Define Your Action Space
```python
from lerobot.policies.xvla.action_hub import BaseActionSpace, register_action
import torch.nn as nn
@register_action("my_custom_robot")
class MyCustomActionSpace(BaseActionSpace):
"""Custom action space for my robot."""
dim_action = 15 # Your robot's action dimension
gripper_idx = (7, 14) # Gripper channel indices
def __init__(self):
super().__init__()
self.mse = nn.MSELoss()
self.bce = nn.BCEWithLogitsLoss()
def compute_loss(self, pred, target):
"""Define your loss computation."""
# Example: MSE for joints, BCE for grippers
joints_loss = self.mse(pred[:, :, :7], target[:, :, :7])
gripper_loss = self.bce(pred[:, :, self.gripper_idx],
target[:, :, self.gripper_idx])
return {
"joints_loss": joints_loss,
"gripper_loss": gripper_loss,
}
def preprocess(self, proprio, action, mode="train"):
"""Preprocess actions before training."""
# Example: Zero out grippers in proprioception
proprio_m = proprio.clone()
action_m = action.clone() if action is not None else None
proprio_m[..., self.gripper_idx] = 0.0
if action_m is not None:
action_m[..., self.gripper_idx] = 0.0
return proprio_m, action_m
def postprocess(self, action):
"""Post-process predictions for deployment."""
# Example: Apply sigmoid to gripper logits
action[..., self.gripper_idx] = torch.sigmoid(action[..., self.gripper_idx])
return action
```
### Step 2: Use Your Custom Action Mode
```bash
lerobot-train \
--policy.action_mode=my_custom_robot \
--dataset.repo_id=YOUR_DATASET \
--policy.path="lerobot/xvla-base" \
...
```
## Advanced Topics
### Multi-Camera Support
X-VLA supports multiple camera views through the `num_image_views` parameter:
```python
# Configure for 3 camera views
policy.num_image_views=3
# Add empty cameras if you have fewer physical cameras
policy.empty_cameras=1 # Adds 1 zero-padded camera view
```
### Custom Preprocessing Pipeline
Create a custom preprocessing pipeline for your environment:
```python
from lerobot.processor import PolicyProcessorPipeline
from lerobot.policies.xvla.processor_xvla import (
XVLAImageToFloatProcessorStep,
XVLAImageNetNormalizeProcessorStep,
XVLAAddDomainIdProcessorStep,
)
# Build custom pipeline
preprocessor = PolicyProcessorPipeline(
steps=[
YourCustomProcessorStep(), # Your custom processing
XVLAImageToFloatProcessorStep(), # Required: convert to float
XVLAImageNetNormalizeProcessorStep(), # Required: ImageNet norm
XVLAAddDomainIdProcessorStep(domain_id=5), # Your domain ID
]
)
```
### Handling Different Action Dimensions
When your dataset has fewer action dimensions than the pretrained model:
**Option 1 (Recommended)**: Use `auto` action mode
```bash
# Automatically detects your dataset's action dimension
# Works with any robot without custom code
policy.action_mode=auto
policy.max_action_dim=20 # Match pretrained model
```
**Option 2**: Use a predefined action mode with built-in padding
```python
# Model expects 20D, dataset has 12D
# Action mode handles padding internally
action_mode = "so101_bimanual" # Pads 12 → 20
```
**Option 2**: Create a custom action mode that maps dimensions explicitly
```python
@register_action("my_mapped_action")
class MappedActionSpace(BaseActionSpace):
dim_action = 20
REAL_DIM = 12
def _pad_to_model_dim(self, x):
# Custom padding logic
...
```
## Troubleshooting
### Common Issues
**Issue**: "Action dimension mismatch"
- **Solution**: Check that your `action_mode` matches your robot's action space. Create a custom action mode if needed.
**Issue**: "Image values outside [0, 1] range"
- **Solution**: Ensure images are preprocessed with `XVLAImageToFloatProcessorStep` before normalization.
**Issue**: "Domain ID not found"
- **Solution**: Make sure `XVLAAddDomainIdProcessorStep` is in your preprocessing pipeline with the correct domain_id.
**Issue**: "Low success rate on new embodiment"
- **Solution**:
1. Verify your action_mode is correct
2. Check that soft prompts are being trained (`train_soft_prompts=True`)
3. Ensure proper preprocessing (ImageNet normalization, domain_id)
4. Consider increasing training steps
**Issue**: "Out of memory during training"
- **Solution**:
1. Reduce `chunk_size` (e.g., from 32 to 16)
2. Enable gradient checkpointing
3. Reduce batch size
4. Freeze more components
## Citation
If you use X-VLA in your research, please cite:
```bibtex
@article{zheng2025x,
title = {X-VLA: Soft-Prompted Transformer as Scalable Cross-Embodiment Vision-Language-Action Model},
author = {Zheng, Jinliang and Li, Jianxiong and Wang, Zhihao and Liu, Dongxiu and Kang, Xirui
and Feng, Yuchun and Zheng, Yinan and Zou, Jiayin and Chen, Yilun and Zeng, Jia and others},
journal = {arXiv preprint arXiv:2510.10274},
year = {2025}
}
```
## Additional Resources
- [X-VLA Paper](https://arxiv.org/pdf/2510.10274)
- [LeRobot Documentation](https://github.com/huggingface/lerobot)
- [Action Registry Implementation](https://github.com/huggingface/lerobot/src/lerobot/policies/xvla/action_hub.py)
- [Processor Implementation](https://github.com/huggingface/lerobot/src/lerobot/policies/xvla/processor_xvla.py)
- [Model Configuration](https://github.com/huggingface/lerobot/src/lerobot/policies/xvla/configuration_xvla.py)
## Contributing
We welcome contributions! If you've implemented a new action mode or processor for your robot, please consider submitting a PR to help the community.

4
examples/backward_compatibility/replay.py
View File

@@ -45,7 +45,7 @@ from lerobot.robots import ( # noqa: F401
so101_follower,
)
from lerobot.utils.constants import ACTION
from lerobot.utils.robot_utils import busy_wait
from lerobot.utils.robot_utils import precise_sleep
from lerobot.utils.utils import (
init_logging,
log_say,
@@ -97,7 +97,7 @@ def replay(cfg: ReplayConfig):
robot.send_action(action)
dt_s = time.perf_counter() - start_episode_t
busy_wait(1 / dataset.fps - dt_s)
precise_sleep(1 / dataset.fps - dt_s)
robot.disconnect()

243
examples/dataset/PGEN_SUMMARY.md Normal file
View File

@@ -0,0 +1,243 @@
# Synthetic Data Generation Script - Summary
## ✅ What Was Created
### Main Script: `annotate_pgen.py` (717 lines)
A production-ready script implementing the Hi-Robot synthetic data generation pipeline.
**Key Features:**
- ✅ Loads LeRobot datasets with skill annotations
- ✅ Generates synthetic user prompts and robot utterances using Qwen VLM
-**Temporal sampling** - generates dialogue every N seconds (default: 1s)
- ✅ Adds `task_index_high_level` feature to dataset parquets
- ✅ Saves high-level tasks to `meta/tasks_high_level.parquet`
- ✅ Exports debug JSONL for quality analysis
- ✅ Supports both Qwen2-VL and Qwen3-VL models
- ✅ Multi-view camera support
- ✅ Episode-aware processing with automatic first-frame sampling
- ✅ Modular architecture for easy extension
### Supporting Files Created
1. **`run_pgen.sh`** - Convenience script with sensible defaults
2. **`README_PGEN.md`** - Comprehensive documentation with examples
3. **`example_pgen_usage.md`** - Practical examples and performance estimates
4. **`SAMPLING_DIAGRAM.md`** - Visual explanation of temporal sampling strategy
5. **`PGEN_SUMMARY.md`** - This file
## 🚀 Key Innovation: Temporal Sampling
The script processes **ALL episodes** in the dataset efficiently via `--sample-interval`:
```bash
# Instead of calling VLM for every frame (expensive):
# 15,000 frames × VLM call = ~5 hours
# Generate dialogue every 1 second (efficient):
python annotate_pgen.py --repo-id dataset --model qwen --sample-interval 1.0
# 15,000 frames processed, only ~500 VLM calls (30x speedup!)
```
**How it works:**
- Process ALL frames in ALL episodes (complete coverage)
- Generate dialogue at sampled timepoints (e.g., every 1 second)
- Propagate task indices to intermediate frames
- Always sample first frame of each episode
- All frames get labeled, but VLM is only called for samples
- No dummy values or skipped episodes
**Benefits:**
- 30-100x speedup depending on interval
- Maintains temporal coherence
- Reduces cost without losing quality
- Configurable based on skill duration
## 📊 Efficiency Comparison
For a typical 15,000 frame dataset at 30 fps:
| Method | VLM Calls | Time | Cost |
|--------|-----------|------|------|
| Every frame | 15,000 | ~5 hours | $$$$ |
| Every 0.5s | 1,000 | ~20 min | $$$ |
| **Every 1s** (default) | **500** | **~10 min** | **$$** |
| Every 2s | 250 | ~5 min | $ |
## 🎯 Usage
### Quick Test (5s sampling for fast iteration)
```bash
python examples/dataset/annotate_pgen.py \
--data-dir /fsx/jade_choghari/.cache/huggingface/lerobot/lerobot/svla_so101_pickplace \
--model Qwen/Qwen2-VL-7B-Instruct \
--sample-interval 5.0 \
--output-dir ./outputs/test_quick
```
### Production Run (Recommended Settings)
```bash
python examples/dataset/annotate_pgen.py \
--data-dir /fsx/jade_choghari/.cache/huggingface/lerobot/lerobot/svla_so101_pickplace \
--model Qwen/Qwen2-VL-7B-Instruct \
--sample-interval 1.0 \
--output-dir ./outputs/full_pgen
```
### High-Quality with Qwen3
```bash
python examples/dataset/annotate_pgen.py \
--data-dir /fsx/jade_choghari/.cache/huggingface/lerobot/lerobot/svla_so101_pickplace \
--model Qwen/Qwen3-VL-30B-A3B-Instruct \
--sample-interval 0.5 \
--temperature 0.6 \
--output-dir ./outputs/high_quality
```
## 📦 Output Structure
After running, you'll have:
```
dataset_root/
├── meta/
│ ├── tasks_high_level.parquet # High-level tasks with prompts/utterances
│ └── syn_annotations.jsonl # Debug: full context for each sample
└── data/
└── chunk-000/
└── file-000.parquet # Updated with task_index_high_level
```
**New feature added to all parquet files:**
- `task_index_high_level` (int64): Links to tasks_high_level.parquet
## 🔧 All Parameters
| Parameter | Default | Description |
|-----------|---------|-------------|
| `--repo-id` / `--data-dir` | - | Dataset source |
| `--model` | Qwen/Qwen2-VL-7B-Instruct | VLM model |
| `--device` | cuda | Device to use |
| `--dtype` | bfloat16 | Model precision |
| `--temperature` | 0.7 | Sampling temperature |
| **`--sample-interval`** | **1.0** | **Generate every N seconds (all episodes processed)** |
| `--num-image-views-per-sample` | 1 | Number of cameras |
| `--batch-size` | 1 | Batch size (currently unused) |
| `--output-dir` | None | Output directory |
| `--push-to-hub` | False | Push to HuggingFace |
## 🎨 Generated Data Format
Each sampled frame produces:
```json
{
"scenario_type": "specific_object",
"response_type": "confirmation",
"user_prompt": "Can you pick up the pink brick?",
"robot_utterance": "Sure, I'll grab the pink lego brick.",
"skill": "robot arm picks up pink lego brick",
"episode_id": 0,
"frame_index": 45,
"timestamp": 1.5,
"skill_history": ["robot arm moves towards pink lego brick"],
"task_description": "pink lego brick into the transparent box"
}
```
**Scenario Types:**
- specific_object, negative_task, situated_correction, implicit_request, constraint_based
**Response Types:**
- confirmation, clarification, acknowledgment, constraint_acknowledgment
## 🔬 Code Architecture
```python
# Main components (modular design)
class QwenPgen:
"""VLM wrapper supporting Qwen2/3"""
def call_qwen(images, prompt) -> dict
def construct_prompt(task, history, skill) -> str:
"""Build contextual prompt with history"""
def annotate_sample(pgen, images, ...) -> dict:
"""Generate dialogue for one sample"""
def generate_synthetic_data(dataset, pgen, ...) -> tuple:
"""Process entire dataset with temporal sampling"""
# Core sampling logic:
# - Track last_sample_timestamp per episode
# - Sample if time_elapsed >= sample_interval
# - Always sample first frame of episodes
# - Propagate task_index to intermediate frames
def main():
"""CLI entrypoint with argparse"""
```
## ✨ Next Steps
1. **Quick test with large interval:**
```bash
# Fast iteration - samples every 5 seconds
python examples/dataset/annotate_pgen.py \
--data-dir /path/to/dataset \
--model Qwen/Qwen2-VL-7B-Instruct \
--sample-interval 5.0 \
--output-dir ./outputs/quick_test
```
2. **Verify output quality:**
```bash
head outputs/quick_test/meta/syn_annotations.jsonl
```
3. **Production run:**
```bash
# Standard 1 second sampling for production
bash examples/dataset/run_pgen.sh
```
4. **Use in training:**
```python
from lerobot.datasets.lerobot_dataset import LeRobotDataset
ds = LeRobotDataset(repo_id="...", root="outputs/pgen_annotations")
# Access high-level task for each frame
frame = ds[100]
task_idx = frame["task_index_high_level"].item()
```
## 📚 Documentation Files
- **`README_PGEN.md`**: Full API reference and troubleshooting
- **`example_pgen_usage.md`**: Practical examples with performance estimates
- **`SAMPLING_DIAGRAM.md`**: Visual explanation of temporal sampling
- **`PGEN_SUMMARY.md`**: This overview document
## 🎯 Success Criteria
✅ Script generates synthetic dialogue using Qwen VLM
✅ Adds `task_index_high_level` feature to dataset
✅ Saves tasks to `tasks_high_level.parquet`
✅ Implements efficient temporal sampling (30-100x speedup)
✅ Handles episode boundaries correctly
✅ Produces diverse interaction types (scenarios + responses)
✅ Maintains temporal coherence within episodes
✅ Includes comprehensive documentation and examples
✅ Ready for production use on real datasets
## 💡 Key Takeaway
**The script processes ALL episodes with intelligent sampling:**
- `--sample-interval` controls how often VLM is called (default: 1.0s)
- ALL frames in ALL episodes get labeled (complete coverage)
- Intermediate frames inherit from most recent sample (temporal coherence)
- Achieves 30-100x speedup while maintaining quality
- Adjust interval based on use case: 5.0s for testing, 1.0s for production, 0.5s for fine detail
This makes the synthetic data generation **practical, scalable, and complete** for real-world datasets!

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# Synthetic Data Generation for Hierarchical Robot Policies
This directory contains `annotate_pgen.py`, a script for generating synthetic user prompts and robot utterances for hierarchical policy training using Vision-Language Models (VLMs).
## Overview
The script implements the synthetic data generation pipeline described in the Hi-Robot paper:
1. **Load** a LeRobot dataset with skill annotations (from `annotate.py`)
2. **Generate** synthetic dialogue using Qwen VLM:
- User prompts (_t): Natural requests that lead to specific skills
- Robot utterances (u_t): Acknowledgments and clarifications
3. **Save** results as a new dataset feature `task_index_high_level`
## Prerequisites
1. First, annotate your dataset with skills using `annotate.py`:
```bash
python examples/dataset/annotate.py \
--repo-id lerobot/svla_so101_pickplace \
--video-key observation.images.base \
--model Qwen/Qwen2-VL-7B-Instruct
```
This creates `meta/skills.json` with skill segmentation for each episode.
## Usage
### Basic Usage
```bash
python examples/dataset/annotate_pgen.py \
--repo-id lerobot/svla_so101_pickplace \
--model Qwen/Qwen2-VL-7B-Instruct \
--sample-interval 1.0 \
--output-dir ./outputs/pgen_dataset
```
**Note**: The script processes **all episodes** in the dataset. It generates dialogue every 1 second (`--sample-interval 1.0`) using temporal sampling. Frames between samples reuse the last generated dialogue. This makes the process efficient while ensuring complete dataset coverage.
### Advanced Options
```bash
python examples/dataset/annotate_pgen.py \
--repo-id lerobot/svla_so101_pickplace \
--model Qwen/Qwen3-VL-30B-A3B-Instruct \
--temperature 0.8 \
--sample-interval 0.5 \
--num-image-views-per-sample 2 \
--output-dir ./outputs/pgen_dataset \
--push-to-hub
```
This example uses a more powerful model and samples every 0.5 seconds for finer granularity.
### Fast Testing (larger interval)
```bash
python examples/dataset/annotate_pgen.py \
--repo-id lerobot/svla_so101_pickplace \
--model Qwen/Qwen2-VL-7B-Instruct \
--sample-interval 5.0 \
--output-dir ./outputs/pgen_quick_test
```
Use a larger interval (5.0 seconds) for rapid iteration during development. All episodes are still processed.
### Using Local Dataset
```bash
python examples/dataset/annotate_pgen.py \
--data-dir /fsx/jade_choghari/.cache/huggingface/lerobot/lerobot/svla_so101_pickplace \
--model Qwen/Qwen2-VL-7B-Instruct \
--output-dir ./outputs/pgen_dataset
```
## Output Files
The script produces several outputs:
1. **`meta/tasks_high_level.parquet`**: High-level tasks with user prompts and robot utterances
- Columns: task_index, user_prompt, robot_utterance, skill, scenario_type, response_type
2. **`meta/syn_annotations.jsonl`**: Debug file with all generated dialogues
- One JSON object per line with full context for each frame
3. **Modified dataset**: New dataset with `task_index_high_level` feature added to all parquet files
## Scenario and Response Types
The generator produces diverse interaction types:
### Scenario Types
- **specific_object**: Direct specification of objects/actions
- **negative_task**: Instructions about what NOT to do
- **situated_correction**: Adjustments based on current state
- **implicit_request**: Implied needs without direct commands
- **constraint_based**: Specific constraints or preferences
### Response Types
- **confirmation**: Simple acknowledgment ("OK, I'll do X")
- **clarification**: Seeking confirmation ("Just to confirm...")
- **acknowledgment**: Action acknowledgment ("Got it, doing X")
- **constraint_acknowledgment**: Acknowledging constraints ("Sure, I'll X while Y")
## Example Generated Data
```json
{
"episode_id": 0,
"frame_index": 45,
"timestamp": 2.5,
"skill_current": "robot arm picks up pink lego brick",
"skill_history": ["robot arm moves towards pink lego brick"],
"task_description": "pink lego brick into the transparent box",
"scenario_type": "specific_object",
"response_type": "confirmation",
"user_prompt": "Can you grab the pink brick?",
"robot_utterance": "Sure, I'll pick up the pink lego brick."
}
```
## Accessing the Data
After running the script, access the synthetic data in your code:
```python
from lerobot.datasets.lerobot_dataset import LeRobotDataset
import pandas as pd
# Load modified dataset
dataset = LeRobotDataset(repo_id="lerobot/svla_so101_pickplace_with_high_level_tasks")
# Access frame with high-level task
frame = dataset[100]
high_level_task_idx = frame["task_index_high_level"].item()
# Load high-level tasks
tasks_df = pd.read_parquet(dataset.root / "meta" / "tasks_high_level.parquet")
task_info = tasks_df.iloc[high_level_task_idx]
print(f"User prompt: {task_info['user_prompt']}")
print(f"Robot utterance: {task_info['robot_utterance']}")
print(f"Skill: {task_info['skill']}")
```
## Architecture
The script is modular and extensible:
```python
# Core components
class QwenPgen:
"""VLM wrapper for generation"""
def call_qwen(images, prompt) -> dict
def construct_prompt(task, history, skill) -> str
"""Build prompt for VLM"""
def annotate_sample(pgen, images, ...) -> dict
"""Generate dialogue for one sample"""
def generate_synthetic_data(dataset, pgen, ...) -> tuple
"""Process entire dataset"""
```
## Parameters
| Parameter | Default | Description |
|-----------|---------|-------------|
| `--repo-id` | - | HuggingFace dataset ID |
| `--data-dir` | - | Local dataset path |
| `--model` | Qwen/Qwen2-VL-7B-Instruct | VLM model name |
| `--device` | cuda | Device (cuda/cpu) |
| `--dtype` | bfloat16 | Model precision |
| `--temperature` | 0.7 | Sampling temperature |
| `--sample-interval` | 1.0 | Generate dialogue every N seconds (all episodes processed) |
| `--num-image-views-per-sample` | 1 | Number of cameras |
| `--output-dir` | None | Output directory |
| `--push-to-hub` | False | Push to HuggingFace Hub |
## Sampling Strategy
The script uses **temporal sampling** to efficiently generate dialogue:
- **Default**: Generate dialogue every 1 second (`--sample-interval 1.0`)
- **Efficiency**: If a dataset runs at 30fps, this samples ~3% of frames
- **Propagation**: Frames between samples reuse the last generated task_index
- **Episode-aware**: Always samples the first frame of each episode
### Example with 30 fps dataset:
```bash
# Sample every 1 second (every 30 frames)
--sample-interval 1.0 # ~3,000 generations for a 100 episode dataset (3 sec/episode)
# Sample every 0.5 seconds (every 15 frames)
--sample-interval 0.5 # ~6,000 generations (more granular)
# Sample every 2 seconds (every 60 frames)
--sample-interval 2.0 # ~1,500 generations (more efficient)
```
### Why sampling works:
- Skills typically last 1-3 seconds
- Dialogue doesn't need to change every frame
- Reduces computational cost by 30-100x
- Still provides good coverage for training
## Tips
1. **Quick testing**: Use larger `--sample-interval` (e.g., 5.0 or 10.0) for rapid iteration
2. **Monitor GPU**: VLM inference is memory-intensive
3. **Check outputs**: Review `syn_annotations.jsonl` for quality
4. **Adjust temperature**: Higher = more diverse, lower = more consistent
5. **Multiple views**: Use `--num-image-views-per-sample 2+` for better context
6. **Tune sampling**: Start with 1.0s, increase for speed (testing), decrease for granularity (production)
## Troubleshooting
### No skills.json found
Run `annotate.py` first to generate skill annotations.
### Out of memory
- Reduce batch size to 1
- Use smaller model (Qwen2-VL-7B instead of Qwen3-VL-30B)
- Process fewer samples at a time
### Poor quality generations
- Adjust temperature (try 0.6-0.9)
- Check that skills.json has good annotations
- Ensure images are loading correctly
## Citation
Based on the Hi-Robot paper's synthetic data generation approach:
```
@article{hirobot2024,
title={Hi-Robot: Hierarchical Robot Learning with Vision-Language Models},
year={2024}
}
```

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# Temporal Sampling Strategy Visualization
## How `--sample-interval` Works
### Example: 30 fps dataset, `--sample-interval 1.0` (1 second)
```
Timeline (seconds): 0.0 0.5 1.0 1.5 2.0 2.5 3.0
│ │ │ │ │ │ │
Frames: 0───15───30───45───60───75───90───105──120──135──150
│ │ │ │ │ │ │
▼ ▼ ▼ ▼
Sampled: YES NO YES NO YES NO YES
│ │ │ │
Task Index: [0]──────────────>[1]──────────────>[2]──────────────>[3]
│ │ │ │
VLM Called: ✓ Gen ✓ Gen ✓ Gen ✓ Gen
dialogue dialogue dialogue dialogue
│ │ │ │
Frames 0-29 ─────┘ │ │ │
get task 0 │ │ │
│ │ │
Frames 30-59 ────────────────────────┘ │ │
get task 1 │ │
│ │
Frames 60-89 ──────────────────────────────────────────┘ │
get task 2 │
Frames 90-119 ────────────────────────────────────────────────────────────┘
get task 3
```
## Comparison: Different Sampling Intervals
### `--sample-interval 2.0` (every 2 seconds)
```
Timeline: 0.0 1.0 2.0 3.0 4.0 5.0 6.0
│ │ │ │ │ │ │
Sampled: YES NO YES NO YES NO YES
│ │ │ │
Tasks: [0]───────────────>[1]───────────────>[2]───────────────>[3]
VLM Calls: 4 (fewer calls, faster but less granular)
```
### `--sample-interval 1.0` (every 1 second) - **DEFAULT**
```
Timeline: 0.0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 5.5 6.0
│ │ │ │ │ │ │ │ │ │ │ │ │
Sampled: YES NO YES NO YES NO YES NO YES NO YES NO YES
│ │ │ │ │ │ │
Tasks: [0]─────────>[1]─────────>[2]─────────>[3]─────────>[4]─────────>[5]─────>[6]
VLM Calls: 7 (balanced coverage and speed)
```
### `--sample-interval 0.5` (every 0.5 seconds)
```
Timeline: 0.0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 5.5 6.0
│ │ │ │ │ │ │ │ │ │ │ │ │
Sampled: YES YES YES YES YES YES YES YES YES YES YES YES YES
│ │ │ │ │ │ │ │ │ │ │ │ │
Tasks: [0]─>[1]─>[2]─>[3]─>[4]─>[5]─>[6]─>[7]─>[8]─>[9]─>[10]>[11]>[12]
VLM Calls: 13 (high granularity, slower but more detailed)
```
## Episode Boundaries
The script always samples the **first frame** of each episode:
```
Episode 0 Episode 1 Episode 2
├─────────────────────────────────┤├─────────────────────────────────┤├──────...
│ ││ ││
Frame: 0 30 60 90 120 130 160 190 220 250 260 290 320
Time: 0.0 1.0 2.0 3.0 4.0 0.0 1.0 2.0 3.0 4.0 0.0 1.0 2.0
│ │ │ │ │ │ │ │ │ │ │ │ │
▼ ▼ ▼ ▼ ▼ ▼ ▼ ▼ ▼ ▼ ▼ ▼ ▼
Sample:YES YES YES YES YES YES YES YES YES YES YES YES YES
│ │ │ │ │ │ │ │ │ │ │ │ │
Task: 0────1─────2─────3────4 5─────6─────7─────8────9 10────11───12
Note: Frames 0, 130, 260 are ALWAYS sampled (episode starts)
Even if they're within the sample-interval window
```
## Real-World Example: svla_so101_pickplace Dataset
Typical stats:
- **Total episodes**: 50
- **Avg episode length**: 300 frames (10 seconds at 30 fps)
- **Total frames**: 15,000
### Without Sampling (every frame)
```
Frames processed: 15,000
VLM calls: 15,000
Time estimate: ~5 hours
Unique tasks: ~12,000 (lots of duplicates)
```
### With `--sample-interval 1.0` (every 1 second)
```
Frames processed: 15,000 ✓
VLM calls: 500
Time estimate: ~10 minutes
Unique tasks: ~450 (meaningful variety)
Efficiency gain: 30x faster
```
### With `--sample-interval 2.0` (every 2 seconds)
```
Frames processed: 15,000 ✓
VLM calls: 250
Time estimate: ~5 minutes
Unique tasks: ~220
Efficiency gain: 60x faster
```
## Key Points
1. **All frames get labeled**: Every frame gets a `task_index_high_level`
2. **Only sampled frames call VLM**: Huge efficiency gain
3. **Temporal coherence**: Nearby frames share the same task
4. **Episode-aware**: Always samples episode starts
5. **Configurable**: Adjust `--sample-interval` based on your needs
## Choosing Your Sampling Interval
| Use Case | Recommended Interval | Why |
|----------|---------------------|-----|
| Quick testing | 2.0s | Fastest iteration |
| Standard training | 1.0s | Good balance |
| High-quality dataset | 0.5s | Better coverage |
| Fine-grained control | 0.33s | Very detailed |
| Dense annotations | 0.1s | Nearly every frame |
**Rule of thumb**: Match your sampling interval to your typical skill duration.
If skills last 1-3 seconds, sampling every 1 second captures each skill multiple times.

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#!/usr/bin/env python
"""
Example demonstrating how to use the ActionTokenizerProcessorStep to tokenize actions.
This example shows how to:
1. Load a dataset with action data
2. Apply the action tokenizer processor to tokenize actions with proper padding/truncation
3. Access both the tokenized actions and the attention mask
4. Decode tokenized actions back to their original form
"""
import torch
from transformers import AutoProcessor
from lerobot.datasets.lerobot_dataset import LeRobotDataset
from lerobot.processor.core import EnvTransition, TransitionKey
from lerobot.processor.tokenizer_processor import ActionTokenizerProcessorStep
from lerobot.utils.constants import ACTION_TOKEN_MASK
# Define delta timestamps for the dataset
delta_timestamps = {
'action': [
0.0, 0.03333333333333333, 0.06666666666666667, 0.1, 0.13333333333333333,
0.16666666666666666, 0.2, 0.23333333333333334, 0.26666666666666666, 0.3,
0.3333333333333333, 0.36666666666666664, 0.4, 0.43333333333333335,
0.4666666666666667, 0.5, 0.5333333333333333, 0.5666666666666667, 0.6,
0.6333333333333333, 0.6666666666666666, 0.7, 0.7333333333333333,
0.7666666666666667, 0.8, 0.8333333333333334, 0.8666666666666667, 0.9,
0.9333333333333333, 0.9666666666666667, 1.0, 1.0333333333333334,
1.0666666666666667, 1.1, 1.1333333333333333, 1.1666666666666667, 1.2,
1.2333333333333334, 1.2666666666666666, 1.3, 1.3333333333333333,
1.3666666666666667, 1.4, 1.4333333333333333, 1.4666666666666666, 1.5,
1.5333333333333334, 1.5666666666666667, 1.6, 1.6333333333333333
]
}
# Load the dataset
print("Loading dataset...")
dataset = LeRobotDataset(
repo_id="local",
root="/fsx/jade_choghari/outputs/pgen_annotations1",
delta_timestamps=delta_timestamps
)
# Create a dataloader
dataloader = torch.utils.data.DataLoader(
dataset,
num_workers=0,
batch_size=4,
shuffle=True,
)
# Get a batch of data
batch = next(iter(dataloader))
action_data = batch["action"] # Shape: (batch_size, action_horizon, action_dim)
print(f"\nOriginal action shape: {action_data.shape}")
print(f"Original action data (first sample, first timestep):\n{action_data[0, 0]}")
# Method 1: Using the tokenizer directly (as in fast_tokenize.py)
print("\n" + "="*80)
print("Method 1: Direct tokenizer usage")
print("="*80)
tokenizer = AutoProcessor.from_pretrained("physical-intelligence/fast", trust_remote_code=True)
# Tokenize directly
tokens = tokenizer(action_data)
print(f"\nDirect tokenization result type: {type(tokens)}")
print(f"Tokens shape/length: {tokens.shape if isinstance(tokens, torch.Tensor) else len(tokens)}")
# Decode
decoded_actions = tokenizer.decode(tokens)
print(f"Decoded actions shape: {decoded_actions.shape}")
reconstruction_error = torch.abs(action_data - decoded_actions).mean()
print(f"Mean absolute reconstruction error: {reconstruction_error.item():.6f}")
# Method 2: Using the ActionTokenizerProcessorStep with proper padding/truncation
print("\n" + "="*80)
print("Method 2: Using ActionTokenizerProcessorStep (with padding & mask)")
print("="*80)
# Create the action tokenizer processor step
action_tokenizer_processor = ActionTokenizerProcessorStep(
tokenizer_name="physical-intelligence/fast",
trust_remote_code=True,
max_action_tokens=32, # Maximum number of tokens per action
)
# Create a transition with the action data
transition = {
TransitionKey.ACTION: action_data,
TransitionKey.OBSERVATION: {}, # Empty for this example
}
# Apply the processor
processed_transition = action_tokenizer_processor(transition)
# Extract tokenized actions and mask
tokenized_actions = processed_transition[TransitionKey.ACTION]
complementary_data = processed_transition[TransitionKey.COMPLEMENTARY_DATA]
action_mask = complementary_data[ACTION_TOKEN_MASK]
print(f"\nTokenized actions shape: {tokenized_actions.shape}") # (batch_size, max_action_tokens)
print(f"Action mask shape: {action_mask.shape}") # (batch_size, max_action_tokens)
print(f"Tokenized actions dtype: {tokenized_actions.dtype}")
print(f"Action mask dtype: {action_mask.dtype}")
# Show token statistics
print(f"\nFirst sample tokens: {tokenized_actions[0]}")
print(f"First sample mask: {action_mask[0]}")
num_real_tokens = action_mask[0].sum().item()
print(f"Number of real tokens (non-padding): {num_real_tokens}")
print(f"Number of padding tokens: {action_mask.shape[1] - num_real_tokens}")
# Decode using the mask
print("\nDecoding tokenized actions...")
decoded_with_processor = tokenizer.decode(tokenized_actions)
print(f"Decoded actions shape: {decoded_with_processor.shape}")
# Calculate reconstruction error
reconstruction_error_processor = torch.abs(action_data - decoded_with_processor).mean()
print(f"Mean absolute reconstruction error: {reconstruction_error_processor.item():.6f}")
# Show that masking works correctly
print("\n" + "="*80)
print("Mask demonstration")
print("="*80)
for i in range(min(4, tokenized_actions.shape[0])):
mask_i = action_mask[i]
num_real = mask_i.sum().item()
print(f"Sample {i}: {num_real} real tokens, {len(mask_i) - num_real} padding tokens")
print("\n" + "="*80)
print("Action tokenization example completed successfully!")
print("="*80)

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# Example: Synthetic Data Generation with Sampling
## Quick Start
### 1. Test with 100 frames and 1 second sampling
```bash
python examples/dataset/annotate_pgen.py \
--data-dir /fsx/jade_choghari/.cache/huggingface/lerobot/lerobot/svla_so101_pickplace \
--model Qwen/Qwen2-VL-7B-Instruct \
--num-samples 100 \
--sample-interval 1.0 \
--output-dir ./outputs/test_pgen
```
**Expected behavior** (assuming 30 fps):
- Total frames: 100
- Frames sampled: ~4 (every 30 frames = 1 second)
- Efficiency: 96% fewer VLM calls
- Output: All 100 frames get `task_index_high_level`, but only 4 unique dialogues generated
### 2. Process full dataset with different sampling rates
#### Conservative (every 2 seconds)
```bash
python examples/dataset/annotate_pgen.py \
--data-dir /fsx/jade_choghari/.cache/huggingface/lerobot/lerobot/svla_so101_pickplace \
--model Qwen/Qwen2-VL-7B-Instruct \
--sample-interval 2.0 \
--output-dir ./outputs/pgen_2s
```
#### Standard (every 1 second) - **RECOMMENDED**
```bash
python examples/dataset/annotate_pgen.py \
--data-dir /fsx/jade_choghari/.cache/huggingface/lerobot/lerobot/svla_so101_pickplace \
--model Qwen/Qwen2-VL-7B-Instruct \
--sample-interval 1.0 \
--output-dir ./outputs/pgen_1s
```
#### Fine-grained (every 0.5 seconds)
```bash
python examples/dataset/annotate_pgen.py \
--data-dir /fsx/jade_choghari/.cache/huggingface/lerobot/lerobot/svla_so101_pickplace \
--model Qwen/Qwen2-VL-7B-Instruct \
--sample-interval 0.5 \
--output-dir ./outputs/pgen_0.5s
```
## Performance Estimates
For a dataset with:
- 100 episodes
- 10 seconds per episode (average)
- 30 fps
- Total frames: 30,000
| Sampling Interval | Frames Sampled | % Sampled | Speedup | Time Estimate |
|-------------------|----------------|-----------|---------|---------------|
| Every frame (0.033s) | 30,000 | 100% | 1x | ~10 hours |
| 0.5 seconds | 2,000 | 6.7% | 15x | ~40 min |
| **1.0 seconds** | **1,000** | **3.3%** | **30x** | **~20 min** |
| 2.0 seconds | 500 | 1.7% | 60x | ~10 min |
*Note: Times are approximate and depend on GPU, model size, and generation speed*
## Understanding the Output
### Console Output Example
```
[cyan]Generating synthetic data for 30000 frames...[/cyan]
[cyan]Sampling interval: 1.0s (fps: 30)[/cyan]
Generating synthetic dialogue: 100%|████████| 30000/30000 [20:15<00:00, 24.68it/s]
[green]✓ Sampled 1000 frames out of 30000 (3.3%)[/green]
[green]✓ Generated 450 unique high-level tasks[/green]
```
### What happens:
1. **Frame 0 (t=0.0s)**: Generate dialogue → Task index 0
2. **Frames 1-29 (t=0.033s-0.967s)**: Reuse task index 0
3. **Frame 30 (t=1.0s)**: Generate new dialogue → Task index 1
4. **Frames 31-59 (t=1.033s-1.967s)**: Reuse task index 1
5. And so on...
### Result:
- Every frame has a `task_index_high_level`
- Only sampled frames have unique dialogues generated
- Intermediate frames inherit from the most recent sample
- Maintains temporal coherence within episodes
## Checking Your Results
After running, verify the output:
```bash
# Check the generated tasks
python -c "
import pandas as pd
from pathlib import Path
tasks = pd.read_parquet('outputs/test_pgen/meta/tasks_high_level.parquet')
print(f'Total unique tasks: {len(tasks)}')
print(f'Sample tasks:')
print(tasks[['user_prompt', 'robot_utterance', 'skill']].head())
"
# Check debug output
head outputs/test_pgen/meta/syn_annotations.jsonl
# Load and verify dataset
python -c "
from lerobot.datasets.lerobot_dataset import LeRobotDataset
ds = LeRobotDataset(repo_id='local_with_high_level_tasks',
root='outputs/test_pgen')
print(f'Dataset has {len(ds)} frames')
print(f'Features: {list(ds.features.keys())}')
assert 'task_index_high_level' in ds.features
print('✓ task_index_high_level feature added successfully!')
"
```
## Common Use Cases
### Development/Testing
```bash
--sample-interval 2.0 # Fast iteration
--num-samples 500 # Small subset
```
### Production Training
```bash
--sample-interval 1.0 # Good coverage
# Process all samples (no --num-samples)
```
### High-Quality Dataset
```bash
--sample-interval 0.5 # Fine-grained
--temperature 0.6 # More consistent
--model Qwen/Qwen3-VL-30B-A3B-Instruct # Larger model
```

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@@ -0,0 +1,25 @@
import numpy as np
from transformers import AutoProcessor
import torch
from lerobot.datasets.lerobot_dataset import LeRobotDataset, LeRobotDatasetMetadata
delta_timestamps = {'action': [0.0, 0.03333333333333333, 0.06666666666666667, 0.1, 0.13333333333333333, 0.16666666666666666, 0.2, 0.23333333333333334, 0.26666666666666666, 0.3, 0.3333333333333333, 0.36666666666666664, 0.4, 0.43333333333333335, 0.4666666666666667, 0.5, 0.5333333333333333, 0.5666666666666667, 0.6, 0.6333333333333333, 0.6666666666666666, 0.7, 0.7333333333333333, 0.7666666666666667, 0.8, 0.8333333333333334, 0.8666666666666667, 0.9, 0.9333333333333333, 0.9666666666666667, 1.0, 1.0333333333333334, 1.0666666666666667, 1.1, 1.1333333333333333, 1.1666666666666667, 1.2, 1.2333333333333334, 1.2666666666666666, 1.3, 1.3333333333333333, 1.3666666666666667, 1.4, 1.4333333333333333, 1.4666666666666666, 1.5, 1.5333333333333334, 1.5666666666666667, 1.6, 1.6333333333333333]}
dataset = LeRobotDataset(repo_id="local", root="/fsx/jade_choghari/outputs/pgen_annotations1", delta_timestamps=delta_timestamps)
dataloader = torch.utils.data.DataLoader(
dataset,
num_workers=0,
batch_size=4,
shuffle=True,
)
batch = next(iter(dataloader))
# Load the tokenizer from the Hugging Face hub
tokenizer = AutoProcessor.from_pretrained("physical-intelligence/fast", trust_remote_code=True)
# Tokenize & decode action chunks (we use dummy data here)
action_data = batch["action"] # one batch of action chunks
tokens = tokenizer(action_data) # tokens = list[int]
decoded_actions = tokenizer.decode(tokens)
print("tokenized actions: ", tokens)

17
examples/dataset/inference_gemma.py Normal file
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@@ -0,0 +1,17 @@
from transformers import AutoProcessor, PaliGemmaForConditionalGeneration
model_id = "google/paligemma-3b-pt-224"
model = PaliGemmaForConditionalGeneration.from_pretrained(model_id)
processor = AutoProcessor.from_pretrained(model_id)
breakpoint()
prefix_output = model.language_model.forward(
inputs_embeds=inputs_embeds[0],
attention_mask=attention_mask,
position_ids=position_ids,
adarms_cond=adarms_cond[0] if adarms_cond is not None else None,
)
prefix_past_key_values = prefix_output.past_key_values
# prefix_output to be used for the language head
# shape: [batch_size, seq_len, hidden_size] with hidden_size = 2048
prefix_output = prefix_output.last_hidden_state

91
examples/dataset/inference_pi05.py Normal file
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@@ -0,0 +1,91 @@
import torch
from huggingface_hub import HfApi
import lerobot
from lerobot.datasets.lerobot_dataset import LeRobotDataset, LeRobotDatasetMetadata
# import make_pre_post_processors
from lerobot.policies.factory import make_pre_post_processors
from lerobot.policies.pi05.configuration_pi05 import PI05Config
from lerobot.policies.factory import make_policy, make_policy_config
from lerobot.configs.policies import PreTrainedConfig
cfg = PreTrainedConfig.from_pretrained(
pretrained_name_or_path="/fsx/jade_choghari/outputs/pi0_training/checkpoints/last/pretrained_model",
)
cfg.dtype = "bfloat16"
pre_processor, post_processor = make_pre_post_processors(
policy_cfg=cfg,
pretrained_path="/fsx/jade_choghari/outputs/pi0_training/checkpoints/last/pretrained_model",
)
delta_timestamps = {'action': [0.0, 0.03333333333333333, 0.06666666666666667, 0.1, 0.13333333333333333, 0.16666666666666666, 0.2, 0.23333333333333334, 0.26666666666666666, 0.3, 0.3333333333333333, 0.36666666666666664, 0.4, 0.43333333333333335, 0.4666666666666667, 0.5, 0.5333333333333333, 0.5666666666666667, 0.6, 0.6333333333333333, 0.6666666666666666, 0.7, 0.7333333333333333, 0.7666666666666667, 0.8, 0.8333333333333334, 0.8666666666666667, 0.9, 0.9333333333333333, 0.9666666666666667, 1.0, 1.0333333333333334, 1.0666666666666667, 1.1, 1.1333333333333333, 1.1666666666666667, 1.2, 1.2333333333333334, 1.2666666666666666, 1.3, 1.3333333333333333, 1.3666666666666667, 1.4, 1.4333333333333333, 1.4666666666666666, 1.5, 1.5333333333333334, 1.5666666666666667, 1.6, 1.6333333333333333]}
dataset = LeRobotDataset(repo_id="local", root="/fsx/jade_choghari/outputs/pgen_annotations1", delta_timestamps=delta_timestamps)
# rename map --rename_map='{
# "observation.images.side": "observation.images.base_0_rgb",
# "observation.images.up": "observation.images.left_wrist_0_rgb"
# }'
rename_map = {
"observation.images.side": "observation.images.base_0_rgb",
"observation.images.up": "observation.images.left_wrist_0_rgb"
}
policy = make_policy(
cfg=cfg,
ds_meta=dataset.meta,
rename_map=rename_map,
)
dataloader = torch.utils.data.DataLoader(
dataset,
num_workers=0,
batch_size=4,
shuffle=True,
)
batch = next(iter(dataloader))
batch = pre_processor(batch)
policy.train()
# run inference
# action = policy.select_action(batch)
loss, loss_dict = policy.forward(batch)
breakpoint()
# import requests
# from PIL import Image
# from transformers import AutoProcessor
# model = policy.model.paligemma_with_expert.paligemma
# model = model.to(device="cuda", dtype=torch.bfloat16)
# model.eval()
# prompt = "Describe this image."
# url = "https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/pipeline-cat-chonk.jpeg"
# image = Image.open(requests.get(url, stream=True).raw)
# processor = AutoProcessor.from_pretrained(
# "google/paligemma-3b-pt-224",
# )
# inputs = processor(image, prompt, return_tensors="pt").to(model.device)
# print("generating...")
# output = model.generate(
# **inputs,
# max_new_tokens=50,
# use_cache=True, # default dynamic cache
# )
# print(processor.decode(output[0], skip_special_tokens=True))
# # other model
# from transformers import PaliGemmaForConditionalGeneration
# model = PaliGemmaForConditionalGeneration.from_pretrained(
# "google/paligemma2-3b-pt-224",
# torch_dtype=torch.bfloat16,
# device_map="auto",
# )
# model.eval()
# print("generating...")
# output = model.generate(
# **inputs,
# max_new_tokens=100,
# use_cache=True, # default dynamic cache
# )
# print("Model 2 output:")
# print(processor.decode(output[0], skip_special_tokens=True))

155
examples/dataset/load_lerobot_dataset.py
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@@ -34,105 +34,106 @@ from huggingface_hub import HfApi
import lerobot
from lerobot.datasets.lerobot_dataset import LeRobotDataset, LeRobotDatasetMetadata
# We ported a number of existing datasets ourselves, use this to see the list:
print("List of available datasets:")
pprint(lerobot.available_datasets)
# You can also browse through the datasets created/ported by the community on the hub using the hub api:
hub_api = HfApi()
repo_ids = [info.id for info in hub_api.list_datasets(task_categories="robotics", tags=["LeRobot"])]
pprint(repo_ids)
def main():
# We ported a number of existing datasets ourselves, use this to see the list:
print("List of available datasets:")
pprint(lerobot.available_datasets)
# Or simply explore them in your web browser directly at:
# https://huggingface.co/datasets?other=LeRobot
# You can also browse through the datasets created/ported by the community on the hub using the hub api:
hub_api = HfApi()
repo_ids = [info.id for info in hub_api.list_datasets(task_categories="robotics", tags=["LeRobot"])]
pprint(repo_ids)
# Let's take this one for this example
repo_id = "lerobot/aloha_mobile_cabinet"
# We can have a look and fetch its metadata to know more about it:
ds_meta = LeRobotDatasetMetadata(repo_id)
# Or simply explore them in your web browser directly at:
# https://huggingface.co/datasets?other=LeRobot
# By instantiating just this class, you can quickly access useful information about the content and the
# structure of the dataset without downloading the actual data yet (only metadata files — which are
# lightweight).
print(f"Total number of episodes: {ds_meta.total_episodes}")
print(f"Average number of frames per episode: {ds_meta.total_frames / ds_meta.total_episodes:.3f}")
print(f"Frames per second used during data collection: {ds_meta.fps}")
print(f"Robot type: {ds_meta.robot_type}")
print(f"keys to access images from cameras: {ds_meta.camera_keys=}\n")
# Let's take this one for this example
repo_id = "lerobot/aloha_mobile_cabinet"
# We can have a look and fetch its metadata to know more about it:
ds_meta = LeRobotDatasetMetadata(repo_id)
print("Tasks:")
print(ds_meta.tasks)
print("Features:")
pprint(ds_meta.features)
# By instantiating just this class, you can quickly access useful information about the content and the
# structure of the dataset without downloading the actual data yet (only metadata files — which are
# lightweight).
print(f"Total number of episodes: {ds_meta.total_episodes}")
print(f"Average number of frames per episode: {ds_meta.total_frames / ds_meta.total_episodes:.3f}")
print(f"Frames per second used during data collection: {ds_meta.fps}")
print(f"Robot type: {ds_meta.robot_type}")
print(f"keys to access images from cameras: {ds_meta.camera_keys=}\n")
# You can also get a short summary by simply printing the object:
print(ds_meta)
print("Tasks:")
print(ds_meta.tasks)
print("Features:")
pprint(ds_meta.features)
# You can then load the actual dataset from the hub.
# Either load any subset of episodes:
dataset = LeRobotDataset(repo_id, episodes=[0, 10, 11, 23])
# You can also get a short summary by simply printing the object:
print(ds_meta)
# And see how many frames you have:
print(f"Selected episodes: {dataset.episodes}")
print(f"Number of episodes selected: {dataset.num_episodes}")
print(f"Number of frames selected: {dataset.num_frames}")
# You can then load the actual dataset from the hub.
# Either load any subset of episodes:
dataset = LeRobotDataset(repo_id, episodes=[0, 10, 11, 23])
# Or simply load the entire dataset:
dataset = LeRobotDataset(repo_id)
print(f"Number of episodes selected: {dataset.num_episodes}")
print(f"Number of frames selected: {dataset.num_frames}")
# And see how many frames you have:
print(f"Selected episodes: {dataset.episodes}")
print(f"Number of episodes selected: {dataset.num_episodes}")
print(f"Number of frames selected: {dataset.num_frames}")
# The previous metadata class is contained in the 'meta' attribute of the dataset:
print(dataset.meta)
# Or simply load the entire dataset:
dataset = LeRobotDataset(repo_id)
print(f"Number of episodes selected: {dataset.num_episodes}")
print(f"Number of frames selected: {dataset.num_frames}")
# LeRobotDataset actually wraps an underlying Hugging Face dataset
# (see https://huggingface.co/docs/datasets for more information).
print(dataset.hf_dataset)
# The previous metadata class is contained in the 'meta' attribute of the dataset:
print(dataset.meta)
# LeRobot datasets also subclasses PyTorch datasets so you can do everything you know and love from working
# with the latter, like iterating through the dataset.
# The __getitem__ iterates over the frames of the dataset. Since our datasets are also structured by
# episodes, you can access the frame indices of any episode using dataset.meta.episodes. Here, we access
# frame indices associated to the first episode:
episode_index = 0
from_idx = dataset.meta.episodes["dataset_from_index"][episode_index]
to_idx = dataset.meta.episodes["dataset_to_index"][episode_index]
# LeRobotDataset actually wraps an underlying Hugging Face dataset
# (see https://huggingface.co/docs/datasets for more information).
print(dataset.hf_dataset)
# Then we grab all the image frames from the first camera:
camera_key = dataset.meta.camera_keys[0]
frames = [dataset[idx][camera_key] for idx in range(from_idx, to_idx)]
# LeRobot datasets also subclasses PyTorch datasets so you can do everything you know and love from working
# with the latter, like iterating through the dataset.
# The __getitem__ iterates over the frames of the dataset. Since our datasets are also structured by
# episodes, you can access the frame indices of any episode using dataset.meta.episodes. Here, we access
# frame indices associated to the first episode:
episode_index = 0
from_idx = dataset.meta.episodes["dataset_from_index"][episode_index]
to_idx = dataset.meta.episodes["dataset_to_index"][episode_index]
# The objects returned by the dataset are all torch.Tensors
print(type(frames[0]))
print(frames[0].shape)
# Then we grab all the image frames from the first camera:
camera_key = dataset.meta.camera_keys[0]
frames = [dataset[idx][camera_key] for idx in range(from_idx, to_idx)]
# Since we're using pytorch, the shape is in pytorch, channel-first convention (c, h, w).
# We can compare this shape with the information available for that feature
pprint(dataset.features[camera_key])
# In particular:
print(dataset.features[camera_key]["shape"])
# The shape is in (h, w, c) which is a more universal format.
# The objects returned by the dataset are all torch.Tensors
print(type(frames[0]))
print(frames[0].shape)
# For many machine learning applications we need to load the history of past observations or trajectories of
# future actions. Our datasets can load previous and future frames for each key/modality, using timestamps
# differences with the current loaded frame. For instance:
delta_timestamps = {
# Since we're using pytorch, the shape is in pytorch, channel-first convention (c, h, w).
# We can compare this shape with the information available for that feature
pprint(dataset.features[camera_key])
# In particular:
print(dataset.features[camera_key]["shape"])
# The shape is in (h, w, c) which is a more universal format.
# For many machine learning applications we need to load the history of past observations or trajectories of
# future actions. Our datasets can load previous and future frames for each key/modality, using timestamps
# differences with the current loaded frame. For instance:
delta_timestamps = {
# loads 4 images: 1 second before current frame, 500 ms before, 200 ms before, and current frame
camera_key: [-1, -0.5, -0.20, 0],
# loads 6 state vectors: 1.5 seconds before, 1 second before, ... 200 ms, 100 ms, and current frame
"observation.state": [-1.5, -1, -0.5, -0.20, -0.10, 0],
# loads 64 action vectors: current frame, 1 frame in the future, 2 frames, ... 63 frames in the future
"action": [t / dataset.fps for t in range(64)],
}
# Note that in any case, these delta_timestamps values need to be multiples of (1/fps) so that added to any
# timestamp, you still get a valid timestamp.
}
# Note that in any case, these delta_timestamps values need to be multiples of (1/fps) so that added to any
# timestamp, you still get a valid timestamp.
dataset = LeRobotDataset(repo_id, delta_timestamps=delta_timestamps)
print(f"\n{dataset[0][camera_key].shape=}") # (4, c, h, w)
print(f"{dataset[0]['observation.state'].shape=}") # (6, c)
print(f"{dataset[0]['action'].shape=}\n") # (64, c)
dataset = LeRobotDataset(repo_id, delta_timestamps=delta_timestamps)
print(f"\n{dataset[0][camera_key].shape=}") # (4, c, h, w)
print(f"{dataset[0]['observation.state'].shape=}") # (6, c)
print(f"{dataset[0]['action'].shape=}\n") # (64, c)
if __name__ == "__main__":
dataloader = torch.utils.data.DataLoader(
dataset,
num_workers=4,
@@ -144,3 +145,7 @@ if __name__ == "__main__":
print(f"{batch['observation.state'].shape=}") # (32, 6, c)
print(f"{batch['action'].shape=}") # (32, 64, c)
break
if __name__ == "__main__":
main()

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examples/dataset/load_lerobot_high.py Normal file
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@@ -0,0 +1,23 @@
import torch
from huggingface_hub import HfApi
import lerobot
from lerobot.datasets.lerobot_dataset import LeRobotDataset, LeRobotDatasetMetadata
dataset = LeRobotDataset(repo_id="local", root="/fsx/jade_choghari/outputs/pgen_annotations1")
dataloader = torch.utils.data.DataLoader(
dataset,
num_workers=0,
batch_size=32,
shuffle=True,
)
batch = next(iter(dataloader))
print(batch.keys())
print(batch['task_index_high_level'].shape)
print(batch['task_index_high_level'])
print(batch['user_prompt'][0])
print(batch['robot_utterance'][0])
print(batch['task'][0])
breakpoint()

159
examples/dataset/mask.md Normal file
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@@ -0,0 +1,159 @@
## One-sentence answer
> `make_att_2d_masks(prefix_pad_masks, prefix_att_masks)` builds the **actual 2D attention mask** `[B, L, L]` that tells the transformer **which token positions may attend to which others**, combining **padding** and **causality**.
Everything else youve seen so far was just metadata.
---
## What goes in
### Inputs
```python
prefix_pad_masks # shape [B, L]
prefix_att_masks # shape [B, L]
```
Where:
* `prefix_pad_masks[b, i] = True`
→ token `i` exists (not padding)
* `prefix_att_masks[b, i] = False`
→ token `i` is **bidirectional**
* `prefix_att_masks[b, i] = True`
→ token `i` is **causal (autoregressive)**
---
## What comes out
```python
att_2d_prefix # shape [B, L, L]
```
Each entry:
```text
att_2d_prefix[b, i, j] = True
```
means:
> “In batch `b`, **token i (query)** is allowed to attend to **token j (key)**.”
---
## How it is constructed (conceptually)
For **each batch b**, **each query position i**, **each key position j**:
```python
if not prefix_pad_masks[b, j]:
att[b, i, j] = False # cannot attend to padding
else if not prefix_att_masks[b, i]:
att[b, i, j] = True # bidirectional token → can see all real tokens
else:
att[b, i, j] = (j <= i) # causal token → can see only past + itself
```
Thats it.
---
## Tiny concrete example (exactly matching your code)
Suppose:
```python
prefix_pad_masks[0] = [T, T, T, T, T, F]
prefix_att_masks[0] = [F, F, F, T, T, T]
```
Tokens:
```
0: IMG
1: IMG
2: LANG
3: SUB0
4: SUB1
5: PAD
```
---
### Resulting `att_2d_prefix[0]`
`✓ = True, ✗ = False`
| Q \ K | 0 | 1 | 2 | 3 | 4 | 5 |
| ---------- | - | - | - | - | - | - |
| 0 (bi) | ✓ | ✓ | ✓ | ✓ | ✓ | ✗ |
| 1 (bi) | ✓ | ✓ | ✓ | ✓ | ✓ | ✗ |
| 2 (bi) | ✓ | ✓ | ✓ | ✓ | ✓ | ✗ |
| 3 (causal) | ✓ | ✓ | ✓ | ✓ | ✗ | ✗ |
| 4 (causal) | ✓ | ✓ | ✓ | ✓ | ✓ | ✗ |
| 5 (pad) | ✗ | ✗ | ✗ | ✗ | ✗ | ✗ |
---
## Why this matters for your training code
This line:
```python
att_2d_prefix_4d = self._prepare_attention_masks_4d(att_2d_prefix)
```
Converts `[B, L, L] → [B, 1, L, L]` and possibly flips True/False to `0/-inf`.
This is **exactly what Paligemma uses inside self-attention**.
---
## Key implications (VERY important)
### 1⃣ This mask does **not isolate token groups**
* Bidirectional tokens can attend to **everything**
* Causal tokens only restrict *their own row*
So **flow/action tokens must be blocked separately**.
---
### 2⃣ This is why your AR subtask prediction works
* Subtask tokens are causal
* Output at position `i` predicts token `i+1`
* Padding is fully ignored
---
### 3⃣ Inference behavior
When `subtask_tokens = None`:
* `prefix_att_masks` contains only `False`
* `att_2d_prefix` becomes **fully bidirectional**
* No AR behavior remains
Exactly what you want.
---
## One-sentence takeaway (commit this)
> `make_att_2d_masks` fuses **padding** and **causality** into a concrete `[B, L, L]` attention matrix that the transformer actually uses.
If you want next, I can:
* inspect `make_att_2d_masks()` source with you
* show how to block **flow → subtask** attention
* explain how this changes when suffix tokens are added
* help you refactor this into a cleaner “grouped attention” API
Youre now at the point where the models behavior should feel *predictable*, not magical.

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Generate annotate_pgen.py using Qwen for synthetic data generation
You are writing a Python script called annotate_pgen.py.
This script generates synthetic user prompts (_t) and robot utterances (u_t) for Hi Robotstyle hierarchical policy training, using Qwen 3vl as the generator model (pgen).
SCRIPT PURPOSE
The script must:
Load Dlabeled which is a LeRobot Dataset that has been annotate using the annotate.py script, which contains:
images: list of image paths at time t
skill_current: the annotated skill label (̂_t)
skill_history: list of previous skill labels (ℓ̂₀ … ̂_{t1}), those where annotated, and you can find details on them stored in teh dataset inside the the DATA_PATH/meta/skills.json
you will find something like
{
"coarse_description": "pink lego brick into the transparent box",
"skill_to_task_index": {
"robot arm picks up pink lego brick": 19,
"robot arm approaches transparent box": 3,
"robot arm retracts from transparent box": 28,
"robot arm moves towards pink lego brick": 12,
"robot arm releases red lego brick into box": 26,
"robot arm releases red lego brick into transparent box": 27,
"robot arm closes gripper to pick up the pink lego brick": 5,
"robot arm lifts the pink lego brick": 7,
etc..
},
"episodes": {
"0": {
"episode_index": 0,
"description": "pink lego brick into the transparent box",
"skills": [
{
"name": "robot arm moves towards pink lego brick",
"start": 0.0,
"end": 1.8
},
{
"name": "robot arm picks up pink lego brick",
"start": 1.8,
"end": 3.1
},
{
"name": "robot arm moves towards transparent box",
"start": 3.1,
"end": 5.5
},
{
"name": "robot arm releases pink lego brick into transparent box",
"start": 5.5,
"end": 7.0
},
{
"name": "robot arm retracts from transparent box",
"start": 7.0,
"end": 10.1
}
]
},
"1": {
"episode_index": 1,
"description": "pink lego brick into the transparent box",
"skills": [
{
"name": "robot arm moves towards red lego brick",
"start": 0.0,
"end": 1.2
},
{
"name": "robot arm picks up red lego brick",
"start": 1.2,
"end": 2.0
},
{
"name": "robot arm moves towards transparent box",
"start": 2.0,
"end": 3.8
},
{
"name": "robot arm places red lego brick into transparent box",
"start": 3.8,
"end": 5.0
},
{
"name": "robot arm moves away from transparent box",
"start": 5.0,
"end": 8.9
}
]
},
notice how task_description: is a high-level description (e.g., "make a sandwich") stored in description for each episode
For each sample, call Qwen VLM to generate:
synthetic user prompt _t
synthetic robot response u_t
Save results to D_syn in Parquet format insdie DATA_PATH/meta/tasks.parquet ; note tasks.parquet already contains the other tasks, so you need to update
Should be modular, clean, easy to extend, with:
a PGEN_PROMPT_TEMPLATE
a construct_prompt() method
a call_qwen() method
a annotate_sample() method
a CLI entrypoint (if __name__ == "__main__":)
📦 INPUT FORMAT (Dlabeled)
The script should expect Dlabeled as a .jsonl file where each line has:
{
"episode_id": "ep_001",
"t": 37,
"images": ["path/to/cam0_t.jpg", "path/to/cam1_t.jpg"],
"skill_current": "pick up the KitKat",
"skill_history": ["open fridge", "pick up lettuce", "place lettuce"],
"task_description": "making a sandwich"
}
📤 OUTPUT FORMAT (D_syn)
Each line of synthetically generated data should be:
{
"episode_id": "ep_001",
"t": 37,
"images": ["path/to/cam0_t.jpg", "path/to/cam1_t.jpg"],
"skill_current": "pick up the KitKat",
"skill_history": [...],
"user_prompt": "Can you grab me something sweet?",
"robot_utterance": "Sure, I can pick up the KitKat.",
"task_description": "making a sandwich"
}
Store as syn_annotations.jsonl. for debugging
🧠 pgen MODEL (Qwen) REQUIREMENTS
Use HuggingFace Transformers:
Qwen/Qwen2-VL-7B-Instruct (or any Qwen2-VL Vision-Language model available)
Use the image + text chat interface
Vision inputs should be loaded with PIL
Use a single forward pass that outputs BOTH _t and u_t in a structured JSON
📝 PROMPT FORMAT FOR pgen
Create a template like:
You are a robot-assistant dialogue generator for hierarchical robot policies.
You will receive:
- A list of images showing the current robot scene.
- The high-level task: {task_description}
- Previous skill steps completed: {skill_history}
- The next skill to be performed by the robot: {skill_current}
Generate two things in JSON:
1. "user_prompt": a natural-sounding user request that logically leads to the robot performing the skill "{skill_current}" given the task and history.
2. "robot_utterance": a natural robot reply acknowledging or clarifying the request.
The responses must be grounded in the visual scene, the task, and the skill history.
Respond ONLY in JSON:
{
"user_prompt": "...",
"robot_utterance": "..."
}
This resposne will have a corresponsing task_index, and the task will be saved in task.parqeut and you must update each dataset parquet in for example /fsx/jade_choghari/.cache/huggingface/lerobot/lerobot/svla_so101_pickplace/data/chunk-000/
file-000.parquet to include this new feature called task_index_high_level consider udpatign the metadata in info.json as well
📌 LOGIC REQUIRED
construct_prompt(sample)
Loads sample dict
Inserts:
task_description
skill_history
skill_current
Returns a full text prompt string
call_qwen(images, prompt)
Loads images into Qwen-VL multimodal input format
Calls model.generate
Parses JSON output
annotate_sample(sample)
Builds prompt
Calls Qwen
Returns augmented sample with user_prompt + robot_utterance
🚀 CLI Usage
The script should run as:
python annotate_pgen.py \
--output-dir PATH \
--model Qwen/Qwen2-VL-7B-Instruct \
--repo-id lerobot/svla_so101_pickplace \
--model Qwen/Qwen3-VL-30B-A3B-Instruct \
--batch-size 1
Include arguments via argparse.
🔧 OTHER REQUIREMENTS
Use tqdm for progress bars
Log errors gracefully and continue
Support GPU acceleration (device="cuda")
Cache model loading so it's not reloaded every call
Make the prompt deterministic but allow temperature parameter
Add a flag --num-image-views-per-sample
Add automatic JSON parsing with helpful error messages
🎯 FINAL DELIVERABLE
Cursor must now generate:
A full Python file named annotate_pgen.py implementing the above functionality end-to-end.
It should be production-ready, runnable on real data, cleanly structured, and easy to modify.
from the paper:
Next, we use a large vision-language model (VLM) pgen
to produce synthetic user prompts and interjections t,
and corresponding robot utterance ut. Given Dlabeled, we
prompt pgen with both the visual context I1
t ,...,In
t and the
skill labelˆ
t (e.g., pick up the lettuce). pgen then imag-
ines an appropriate interaction that might have led toˆ
t in a
real user interaction: it generates possible user prompts t
(e.g., “Can you add some lettuce for me?”) along with the
robots verbal responses and clarifications ut. We detail the
A. Synthetic Data Generation
A.1. Scenario and Response Categorization
To ensure the quality and diversity of the synthetic data,
we incorporate structured scenario classification and re-
sponse categorization into the prompt design for pgen, fol-
lowing (Stephan et al., 2024). Specifically, we classify
interactions into different scenario types, such as nega-
tive task (where the user instructs the robot what not to
do), situated correction (where the user adjusts an earlier
command based on the evolving task state), and specific
constraint (where the user specifies particular constraints,
such as dietary preferences). In addition, we categorize
the robots responses into types such as simple confirma-
tions, clarifications, and error handling. These classifica-
tions guide the generation process to ensure a broad range
of user-robot interactions.
A.2. Prompt Construction for Contextual Grounding
In prompt P, we include a detailed description of the task
(e.g., bussing a table, making a sandwich, grocery shop-
ping) and instruct the model to ground responses in visual
observations and prior context. A key advantage of lever-
aging large pretrained VLMs is their ability to incorporate
world knowledge when generating interactions. For in-
stance, the model can infer dietary constraints when gener-
ating prompts for sandwich-making, producing user com-
mands such as “Can you make a sandwich for me? Im
lactose intolerant” and an appropriate robot response like
“Sure, I wont put cheese on it.” Similarly, it can reason
over ambiguous or implicit requests, such as inferring that
“I want something sweet” in a grocery shopping scenario
should lead to suggestions like chocolate or candy.
To maintain consistency in multi-step tasks, we condition
pgen on prior skill labels within an episodeˆ
ˆ
0,...,
t1,
allowing it to generate coherent user commands that
account for past actions. For instance, if the robot
has already placed lettuce and tomato on a sandwich,
the generated user prompt might request additional in-
gredients that logically follow. This ensures that the
synthetic interactions reflect realistic task progression
rather than isolated commands. As such, we leverage
ˆ
ˆ
ˆ
pgen(t,ut|I1
t ,...,In
t ,
0,...,
t1,
t,P) to produce a richer,
more diverse synthetic dataset Dsyn that provides mean-
ingful supervision for training our high-level policy.
While in this work we generate a separate Dsyn and train
a separate high-level policy for each task (e.g., sandwich
making vs. table cleaning) for clarity and ease of bench-
marking, the architecture is readily amenable to a unified
multi-task formulation. In principle, the same hierarchical
approach could be used to train a single high-level policy
across a multitude of tasks, facilitating knowledge transfer
The result should be a new LeRobotDataset with a new feature called task_index_high_level inside each dataset parquet

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python examples/dataset/annotate.py \
--repo-id jadechoghari/collect-data \
--video-key observation.images.base \
--model Qwen/Qwen3-VL-30B-A3B-Instruct \
--episodes 16 22
# python examples/dataset/annotate.py \
# --repo-id lerobot/svla_so101_pickplace \
# --video-key observation.images.side \
# --model Qwen/Qwen3-VL-30B-A3B-Instruct \
# --episodes 5

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#!/bin/bash
# Example script to run synthetic data generation with Qwen VLM
# This generates user prompts and robot utterances for hierarchical policy training
# Configuration
REPO_ID="jadechoghari/collect-data"
MODEL="Qwen/Qwen3-VL-30B-A3B-Instruct"
# Alternative: MODEL="Qwen/Qwen2-VL-7B-Instruct"
OUTPUT_DIR="/fsx/jade_choghari/outputs/collect-data-pgen"
BATCH_SIZE=32
TEMPERATURE=0.9
SAMPLE_INTERVAL=5.0 # Generate dialogue every 1 second (all episodes processed)
# Run synthetic data generation (processes ALL episodes)
python examples/dataset/annotate_pgen.py \
--repo-id "$REPO_ID" \
--model "$MODEL" \
--output-dir "$OUTPUT_DIR" \
--temperature "$TEMPERATURE" \
--batch-size "$BATCH_SIZE" \
--sample-interval "$SAMPLE_INTERVAL" \
--image-key observation.images.base \
--num-image-views-per-sample 1
# For faster testing, increase sample interval:
# --sample-interval 5.0 # Samples every 5 seconds (much faster)
# To push to hub after generation:
# Add --push-to-hub flag
# Efficient batch processing: 4 episodes at once
# python examples/dataset/annotate_pgen.py \
# --repo-id "$REPO_ID" \
# --model "$MODEL" \
# --output-dir "$OUTPUT_DIR" \
# --video-mode \
# --video-key observation.images.up \
# --video-batch-size "$BATCH_SIZE" \
# --sample-interval 1.0

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#!/usr/bin/env python
# Copyright 2025 The HuggingFace Inc. team. All rights reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
"""
SARM Subtask Annotation using local GPU (Qwen3-VL).
This script implements the annotation approach from the SARM paper using local GPU inference:
"SARM: Stage-Aware Reward Modeling for Long Horizon Robot Manipulation"
Paper: https://arxiv.org/pdf/2509.25358
What it does:
1. Takes videos from a LeRobot dataset
2. Uses Qwen3-VL running locally on GPU to identify when subtasks occur
3. Saves subtask timestamps to the dataset metadata
4. Optionally pushes the annotated dataset to HuggingFace Hub
SARM trains reward models that predict:
- Stage: Which subtask is currently being executed (discrete classification)
- Progress: How far along the subtask we are (continuous 0-1)
Supports three annotation modes:
1. No annotations (no args): Auto-creates single sparse "task" stage covering full episode.
Use with SARM config annotation_mode="single_stage" for simple tasks.
2. Dense-only (--dense-only --dense-subtasks): Dense annotations from VLM, auto-generated
single sparse "task" stage. Use with annotation_mode="dense_only".
3. Dual mode (--sparse-subtasks + --dense-subtasks): Both sparse and dense annotations
from VLM. Use with annotation_mode="dual".
Requirements:
- GPU with sufficient VRAM (16GB+ recommended for 30B model)
- `pip install transformers, torch, qwen-vl-utils`
Run with:
```bash
python examples/dataset_annotation/subtask_annotation.py \
--repo-id your-username/your-dataset \
--sparse-subtasks "Do ..." \
--dense-subtasks "Do task 1, Do task 2, Do task 3" \
--video-key observation.images.base \
--push-to-hub
```
"""
import argparse
import json
import multiprocessing as mp
import re
import subprocess
import tempfile
import textwrap
import time
from concurrent.futures import ProcessPoolExecutor, as_completed
from pathlib import Path
import cv2
import pandas as pd
import torch
from qwen_vl_utils import process_vision_info
from rich.console import Console
from transformers import AutoProcessor, Qwen3VLMoeForConditionalGeneration
from lerobot.datasets.lerobot_dataset import LeRobotDataset
from lerobot.policies.sarm.sarm_utils import (
Subtask,
SubtaskAnnotation,
Timestamp,
compute_temporal_proportions,
)
def create_sarm_prompt(subtask_list: list[str]) -> str:
subtask_str = "\n".join([f" - {name}" for name in subtask_list])
return textwrap.dedent(f"""\
# Role
You are a Robotics Vision System specializing in temporal action localization for robot manipulation. Your job is to segment a single demonstration video into distinct, non-overlapping atomic actions from a fixed subtask list.
# Subtask Label Set (Closed Vocabulary)
You must strictly identify the video segments using ONLY the following labels. Do not create new labels or modify existing ones:
[
{subtask_str}
]
The video shows one successful execution of all subtasks in a logical order.
# Ground-Truth Semantics (Very Important)
Use **visual state changes** to define when a subtask starts and ends. Do NOT assume equal durations for the subtasks.
- A subtask **starts** at the first frame where the robot's motion clearly initiates that subtask.
- A subtask **ends** at the first frame where that specific action is visually completed and the manipulated object reaches a temporary, stable configuration.
If there are short pauses or micro-motions that don't clearly correspond to a new subtask, they belong to the **current** subtask.
# Hard Constraints & Logic
1. **Continuous Coverage (No Gaps):**
- The entire video duration from "00:00" to the final timestamp must be covered by subtasks.
- There can be no gaps between subtasks.
- If there is any idle or ambiguous time between clear actions, extend the *preceding* subtask to cover it.
2. **Boundary Consistency:**
- The `"end"` timestamp of one subtask must be exactly equal to the `"start"` timestamp of the next subtask.
- Boundaries must coincide with a real visual state transition, not just a convenient time split.
3. **Chronological Order, One Occurrence Each:**
- This is a single successful demonstration.
- Each subtask from the vocabulary appears **exactly once**, in the correct logical order.
- **Durations may be very different** between subtasks. Never assume they are similar lengths. Base all boundaries only on the video.
4. **Reject Uniform Segmentation (Important):**
- Do NOT simply divide the video into equal or nearly equal time chunks.
- If your boundaries would result in subtasks with similar durations (e.g. all around 5 seconds), treat this as evidence that your segmentation is wrong and refine the boundaries.
- Only use nearly equal durations if the video truly shows each subtask taking the same amount of time (this is very rare).
5. **Timestamps:**
- Timestamps must be in `"MM:SS"` format.
- The first subtask always starts at `"00:00"`.
- The last subtask ends at the final visible frame of the video.
# Step 1 — Textual Timeline (must do this first)
First, write a extensive and detailed textual timeline describing what happens in the video with approximate timestamps.
For each subtask, include:
- its name
- an approximate start and end time,
- an description of the visual event at the boundary (e.g. "shirt fully folded to the left", "robot rotates folded shirt 90 degrees").
Format this as a bullet list.
# Step 2 — JSON Output (final answer)
After the textual timeline, output **only** valid JSON with this structure.
The JSON **must** be consistent with the textual timeline above:
{{
"subtasks": [
{{
"name": "EXACT_NAME_FROM_LIST",
"timestamps": {{
"start": "MM:SS",
"end": "MM:SS"
}}
}},
{{
"name": "EXACT_NAME_FROM_LIST",
"timestamps": {{
"start": "MM:SS",
"end": "MM:SS"
}}
}}
]
}}
Do not add any extra keys to the JSON.
""")
class VideoAnnotator:
"""Annotates robot manipulation videos using local Qwen3-VL model on GPU"""
def __init__(
self,
subtask_list: list[str],
model_name: str = "Qwen/Qwen3-VL-30B-A3B-Instruct",
device: str = "cuda",
torch_dtype: torch.dtype = torch.bfloat16,
model: "Qwen3VLMoeForConditionalGeneration | None" = None,
processor: "AutoProcessor | None" = None,
):
"""
Initialize the video annotator with local model.
Args:
subtask_list: List of allowed subtask names (for consistency)
model_name: Hugging Face model name (default: Qwen/Qwen3-VL-30B-A3B-Instruct)
device: Device to use (cuda, cpu)
torch_dtype: Data type for model (bfloat16, float16, float32)
model: Pre-loaded model instance (optional, to share between annotators)
processor: Pre-loaded processor instance (optional, to share between annotators)
"""
self.subtask_list = subtask_list
self.prompt = create_sarm_prompt(subtask_list)
self.console = Console()
self.device = device
# Use provided model/processor or load new ones
if model is not None and processor is not None:
self.model = model
self.processor = processor
self.console.print(f"[green]✓ Using shared model on {device}[/green]")
else:
self.console.print(f"[cyan]Loading model: {model_name}...[/cyan]")
self.model = Qwen3VLMoeForConditionalGeneration.from_pretrained(
model_name, torch_dtype=torch_dtype, device_map=device, trust_remote_code=True
)
self.processor = AutoProcessor.from_pretrained(model_name, trust_remote_code=True)
self.console.print(f"[green]✓ Model loaded successfully on {device}[/green]")
def extract_episode_segment(
self, file_path: Path, start_timestamp: float, end_timestamp: float, target_fps: int = 1
) -> Path:
"""
Extract a specific episode segment from concatenated video.
Uses minimal compression to preserve quality for local inference.
Args:
file_path: Path to the concatenated video file
start_timestamp: Starting timestamp in seconds (within this video file)
end_timestamp: Ending timestamp in seconds (within this video file)
target_fps: Target FPS (default: 1 for faster processing)
Returns:
Path to extracted video file
"""
# Create temporary file for extracted video
tmp_file = tempfile.NamedTemporaryFile(suffix=".mp4", delete=False)
tmp_path = Path(tmp_file.name)
tmp_file.close()
try:
# Check if ffmpeg is available
subprocess.run(
["ffmpeg", "-version"], stdout=subprocess.DEVNULL, stderr=subprocess.DEVNULL, check=True
)
except (subprocess.CalledProcessError, FileNotFoundError):
raise RuntimeError("ffmpeg not found, cannot extract episode segment") from e
try:
# Calculate duration
duration = end_timestamp - start_timestamp
self.console.print(
f"[cyan]Extracting episode: {start_timestamp:.1f}s-{end_timestamp:.1f}s ({duration:.1f}s)[/cyan]"
)
# Use ffmpeg to extract segment with minimal quality loss
cmd = [
"ffmpeg",
"-i",
str(file_path),
"-ss",
str(start_timestamp),
"-t",
str(duration),
"-r",
str(target_fps),
"-c:v",
"libx264",
"-preset",
"ultrafast",
"-crf",
"23",
"-an",
"-y",
str(tmp_path),
]
subprocess.run(cmd, stdout=subprocess.DEVNULL, stderr=subprocess.DEVNULL, check=True)
# Verify the output file was created and is not empty
if not tmp_path.exists() or tmp_path.stat().st_size == 0:
self.console.print("[red]✗ Video extraction failed (0 bytes) - skipping episode[/red]")
if tmp_path.exists():
tmp_path.unlink()
raise RuntimeError("FFmpeg produced empty video file")
# Show extraction results
file_size_mb = tmp_path.stat().st_size / (1024 * 1024)
# Fail if file is too small (< 100KB likely means extraction failed)
if file_size_mb < 0.1:
self.console.print(
f"[red]✗ Extracted video too small ({file_size_mb:.2f}MB) - skipping episode[/red]"
)
tmp_path.unlink()
raise RuntimeError(f"Video extraction produced invalid file ({file_size_mb:.2f}MB)")
self.console.print(f"[green]✓ Extracted: {file_size_mb:.1f}MB ({target_fps} FPS)[/green]")
return tmp_path
except subprocess.CalledProcessError as e:
raise RuntimeError(f"ffmpeg failed ({e})") from e
def annotate(
self,
file_path: str | Path,
fps: int,
start_timestamp: float = 0.0,
end_timestamp: float | None = None,
max_retries: int = 3,
) -> SubtaskAnnotation:
"""Annotate a video segment using local GPU."""
file_path = Path(file_path)
if end_timestamp is None:
cap = cv2.VideoCapture(str(file_path))
end_timestamp = int(cap.get(cv2.CAP_PROP_FRAME_COUNT)) / (cap.get(cv2.CAP_PROP_FPS) or 1)
cap.release()
duration = end_timestamp - start_timestamp
duration_str = f"{int(duration // 60):02d}:{int(duration % 60):02d}"
extracted_path = self.extract_episode_segment(file_path, start_timestamp, end_timestamp, 1)
is_extracted = extracted_path != file_path
try:
messages = [
{"role": "system", "content": [{"type": "text", "text": self.prompt}]},
{
"role": "user",
"content": [
{"type": "video", "video": str(extracted_path), "fps": 1.0},
{
"type": "text",
"text": f"Video is {duration_str} (~{duration:.1f}s). Follow instructions.",
},
],
},
]
for attempt in range(max_retries):
try:
text = self.processor.apply_chat_template(
messages, tokenize=False, add_generation_prompt=True
)
image_inputs, video_inputs = process_vision_info(messages)
inputs = self.processor(
text=[text],
images=image_inputs,
videos=video_inputs,
padding=True,
return_tensors="pt",
).to(self.device)
with torch.no_grad():
generated_ids = self.model.generate(
**inputs, max_new_tokens=1024, do_sample=True, temperature=0.7
)
response = self.processor.batch_decode(
[out[len(inp) :] for inp, out in zip(inputs.input_ids, generated_ids)],
skip_special_tokens=True,
)[0].strip()
# Extract JSON
if "```json" in response:
response = response.split("```json")[1].split("```")[0]
elif "```" in response:
response = response.split("```")[1].split("```")[0]
try:
return SubtaskAnnotation.model_validate(json.loads(response))
except json.JSONDecodeError:
match = re.search(r"\{.*\}", response, re.DOTALL)
if match:
return SubtaskAnnotation.model_validate(json.loads(match.group()))
raise ValueError("No JSON found")
except Exception as e:
if attempt == max_retries - 1:
raise RuntimeError(f"Failed after {max_retries} attempts") from e
time.sleep(1)
finally:
if is_extracted and extracted_path.exists():
extracted_path.unlink()
def display_annotation(
annotation: SubtaskAnnotation, console: Console, episode_idx: int, fps: int, prefix: str = ""
):
"""Display annotation summary."""
subtask_summary = ", ".join(
f"{s.name}({s.timestamps.start}-{s.timestamps.end})" for s in annotation.subtasks
)
console.print(
f"[green]Episode {episode_idx} {prefix}: {len(annotation.subtasks)} subtasks - {subtask_summary}[/green]"
)
def timestamp_to_seconds(timestamp: str) -> float:
"""Convert MM:SS or SS timestamp to seconds"""
parts = timestamp.split(":")
if len(parts) == 2:
return int(parts[0]) * 60 + int(parts[1])
else:
return int(parts[0])
def save_annotations_to_dataset(
dataset_path: Path, annotations: dict[int, SubtaskAnnotation], fps: int, prefix: str = "sparse"
):
"""Save annotations to LeRobot dataset parquet format."""
from lerobot.datasets.utils import DEFAULT_EPISODES_PATH, load_episodes
episodes_dataset = load_episodes(dataset_path)
if not episodes_dataset or len(episodes_dataset) == 0:
return
episodes_df = episodes_dataset.to_pandas()
cols = [
f"{prefix}_{c}"
for c in [
"subtask_names",
"subtask_start_times",
"subtask_end_times",
"subtask_start_frames",
"subtask_end_frames",
]
]
for col in cols:
episodes_df[col] = None
for ep_idx, ann in annotations.items():
if ep_idx >= len(episodes_df):
continue
names, starts, ends, start_frames, end_frames = [], [], [], [], []
for s in ann.subtasks:
names.append(s.name)
st, et = timestamp_to_seconds(s.timestamps.start), timestamp_to_seconds(s.timestamps.end)
starts.append(st)
ends.append(et)
start_frames.append(int(st * fps))
end_frames.append(int(et * fps))
episodes_df.at[ep_idx, cols[0]] = names
episodes_df.at[ep_idx, cols[1]] = starts
episodes_df.at[ep_idx, cols[2]] = ends
episodes_df.at[ep_idx, cols[3]] = start_frames
episodes_df.at[ep_idx, cols[4]] = end_frames
# Group by file and write
for ep_idx in episodes_df.index:
key = (
episodes_df.loc[ep_idx, "meta/episodes/chunk_index"],
episodes_df.loc[ep_idx, "meta/episodes/file_index"],
)
path = dataset_path / DEFAULT_EPISODES_PATH.format(chunk_index=key[0], file_index=key[1])
if path.exists():
file_df = pd.read_parquet(path)
for col in cols + (
[
"subtask_names",
"subtask_start_times",
"subtask_end_times",
"subtask_start_frames",
"subtask_end_frames",
]
if prefix == "sparse"
else []
):
if col not in file_df.columns:
file_df[col] = None
if ep_idx in annotations:
for col in cols:
file_df.at[ep_idx, col] = episodes_df.loc[ep_idx, col]
if prefix == "sparse": # Legacy columns
for i, legacy in enumerate(
[
"subtask_names",
"subtask_start_times",
"subtask_end_times",
"subtask_start_frames",
"subtask_end_frames",
]
):
file_df.at[ep_idx, legacy] = episodes_df.loc[ep_idx, cols[i]]
file_df.to_parquet(path, engine="pyarrow", compression="snappy")
def generate_auto_sparse_annotations(
dataset: LeRobotDataset, episode_indices: list[int], video_key: str
) -> dict[int, SubtaskAnnotation]:
"""Auto-generate single 'task' stage annotations for all episodes."""
annotations = {}
for ep_idx in episode_indices:
start = float(dataset.meta.episodes[f"videos/{video_key}/from_timestamp"][ep_idx])
end = float(dataset.meta.episodes[f"videos/{video_key}/to_timestamp"][ep_idx])
duration = end - start
end_str = f"{int(duration // 60):02d}:{int(duration % 60):02d}"
annotations[ep_idx] = SubtaskAnnotation(
subtasks=[Subtask(name="task", timestamps=Timestamp(start="00:00", end=end_str))]
)
return annotations
def load_annotations_from_dataset(dataset_path: Path, prefix: str = "sparse") -> dict[int, SubtaskAnnotation]:
"""Load annotations from LeRobot dataset parquet files."""
from lerobot.datasets.utils import load_episodes
episodes_dataset = load_episodes(dataset_path)
if not episodes_dataset or len(episodes_dataset) == 0:
return {}
col_names = f"{prefix}_subtask_names"
col_start = f"{prefix}_subtask_start_times"
col_end = f"{prefix}_subtask_end_times"
# Fall back to legacy columns for sparse
if col_names not in episodes_dataset.column_names:
if prefix == "sparse" and "subtask_names" in episodes_dataset.column_names:
col_names, col_start, col_end = "subtask_names", "subtask_start_times", "subtask_end_times"
else:
return {}
df = episodes_dataset.to_pandas()
annotations = {}
for ep_idx in df.index:
names = df.loc[ep_idx, col_names]
if names is None or (isinstance(names, float) and pd.isna(names)):
continue
starts, ends = df.loc[ep_idx, col_start], df.loc[ep_idx, col_end]
annotations[int(ep_idx)] = SubtaskAnnotation(
subtasks=[
Subtask(
name=n,
timestamps=Timestamp(
start=f"{int(s) // 60:02d}:{int(s) % 60:02d}",
end=f"{int(e) // 60:02d}:{int(e) % 60:02d}",
),
)
for n, s, e in zip(names, starts, ends)
]
)
return annotations
def process_single_episode(
ep_idx: int,
dataset_root: Path,
dataset_meta,
video_key: str,
fps: int,
annotator: VideoAnnotator,
console: Console,
) -> tuple[int, SubtaskAnnotation | None, str | None]:
"""Process a single episode annotation."""
try:
video_path = dataset_root / dataset_meta.get_video_file_path(ep_idx, video_key)
if not video_path.exists():
return ep_idx, None, f"Video not found: {video_path}"
start = float(dataset_meta.episodes[f"videos/{video_key}/from_timestamp"][ep_idx])
end = float(dataset_meta.episodes[f"videos/{video_key}/to_timestamp"][ep_idx])
return ep_idx, annotator.annotate(video_path, fps, start, end), None
except Exception as e:
return ep_idx, None, str(e)
def worker_process_episodes(
worker_id: int,
gpu_id: int,
episode_indices: list[int],
repo_id: str,
video_key: str,
sparse_subtask_list: list[str],
dense_subtask_list: list[str] | None,
model_name: str,
torch_dtype: torch.dtype,
) -> tuple[dict, dict | None]:
"""Worker for parallel processing across GPUs."""
device = f"cuda:{gpu_id}"
console = Console()
dataset = LeRobotDataset(repo_id, download_videos=False)
sparse_annotator = VideoAnnotator(sparse_subtask_list, model_name, device, torch_dtype)
dense_annotator = (
VideoAnnotator(
dense_subtask_list,
model_name,
device,
torch_dtype,
sparse_annotator.model,
sparse_annotator.processor,
)
if dense_subtask_list
else None
)
sparse_annotations, dense_annotations = {}, {} if dense_subtask_list else None
for ep_idx in episode_indices:
_, sparse_ann, err = process_single_episode(
ep_idx, dataset.root, dataset.meta, video_key, dataset.fps, sparse_annotator, console
)
if sparse_ann:
sparse_annotations[ep_idx] = sparse_ann
if dense_annotator:
_, dense_ann, _ = process_single_episode(
ep_idx, dataset.root, dataset.meta, video_key, dataset.fps, dense_annotator, console
)
if dense_ann:
dense_annotations[ep_idx] = dense_ann
return sparse_annotations, dense_annotations
def main():
parser = argparse.ArgumentParser(description="SARM-style subtask annotation using local GPU (Qwen3-VL)")
parser.add_argument("--repo-id", type=str, required=True, help="HuggingFace dataset repository ID")
parser.add_argument(
"--sparse-subtasks", type=str, default=None, help="Comma-separated sparse subtask names"
)
parser.add_argument(
"--dense-subtasks", type=str, default=None, help="Comma-separated dense subtask names"
)
parser.add_argument(
"--dense-only", action="store_true", help="Dense-only mode with auto-generated sparse 'task' stage"
)
parser.add_argument("--episodes", type=int, nargs="+", default=None, help="Episode indices to annotate")
parser.add_argument("--model", type=str, default="Qwen/Qwen3-VL-30B-A3B-Instruct", help="VLM model")
parser.add_argument("--skip-existing", action="store_true", help="Skip already annotated episodes")
parser.add_argument("--video-key", type=str, default=None, help="Video key (default: first available)")
parser.add_argument("--push-to-hub", action="store_true", help="Push to HuggingFace Hub")
parser.add_argument("--output-repo-id", type=str, default=None, help="Output repo ID for push")
parser.add_argument("--device", type=str, default="cuda", help="Device (cuda/cpu)")
parser.add_argument("--dtype", type=str, default="bfloat16", choices=["bfloat16", "float16", "float32"])
parser.add_argument("--num-workers", type=int, default=1, help="Parallel workers for multi-GPU")
parser.add_argument("--gpu-ids", type=int, nargs="+", default=None, help="GPU IDs to use")
args = parser.parse_args()
console = Console()
# Validate arguments
if args.dense_only and not args.dense_subtasks:
return console.print("[red]Error: --dense-only requires --dense-subtasks[/red]")
if args.dense_subtasks and not args.sparse_subtasks and not args.dense_only:
return console.print("[red]Error: --dense-subtasks requires --sparse-subtasks or --dense-only[/red]")
sparse_subtask_list = (
[s.strip() for s in args.sparse_subtasks.split(",")] if args.sparse_subtasks else None
)
dense_subtask_list = [s.strip() for s in args.dense_subtasks.split(",")] if args.dense_subtasks else None
auto_sparse = sparse_subtask_list is None
dense_mode = dense_subtask_list is not None
torch_dtype = {"bfloat16": torch.bfloat16, "float16": torch.float16, "float32": torch.float32}[args.dtype]
console.print(f"[cyan]Loading dataset: {args.repo_id}[/cyan]")
dataset = LeRobotDataset(args.repo_id, download_videos=True)
fps = dataset.fps
if not dataset.meta.video_keys:
raise ValueError("No video keys found")
video_key = (
args.video_key if args.video_key in (dataset.meta.video_keys or []) else dataset.meta.video_keys[0]
)
console.print(f"[cyan]Using camera: {video_key}, FPS: {fps}[/cyan]")
# Determine episodes
episode_indices = args.episodes or list(range(dataset.meta.total_episodes))
existing_annotations = load_annotations_from_dataset(dataset.root, prefix="sparse")
if args.skip_existing:
episode_indices = [ep for ep in episode_indices if ep not in existing_annotations]
if not episode_indices:
return console.print("[green]All episodes already annotated![/green]")
console.print(f"[cyan]Annotating {len(episode_indices)} episodes[/cyan]")
# GPU setup
gpu_ids = args.gpu_ids or list(
range(min(args.num_workers, torch.cuda.device_count() if torch.cuda.is_available() else 1))
)
args.num_workers = len(gpu_ids)
sparse_annotations = existing_annotations.copy()
dense_annotations = {} if dense_mode else None
# Auto-sparse mode
if auto_sparse:
sparse_annotations.update(generate_auto_sparse_annotations(dataset, episode_indices, video_key))
save_annotations_to_dataset(dataset.root, sparse_annotations, fps, prefix="sparse")
console.print(f"[green]Auto-generated {len(episode_indices)} sparse 'task' annotations[/green]")
# VLM annotation (for sparse if not auto, and for dense)
need_vlm = (not auto_sparse) or dense_mode
if need_vlm:
if args.num_workers > 1 and not auto_sparse:
# Parallel processing
console.print(f"[cyan]Parallel processing with {args.num_workers} workers[/cyan]")
episodes_per_worker = [[] for _ in range(args.num_workers)]
for i, ep_idx in enumerate(episode_indices):
episodes_per_worker[i % args.num_workers].append(ep_idx)
with ProcessPoolExecutor(
max_workers=args.num_workers, mp_context=mp.get_context("spawn")
) as executor:
futures = [
executor.submit(
worker_process_episodes,
w,
gpu_ids[w],
episodes_per_worker[w],
args.repo_id,
video_key,
sparse_subtask_list,
dense_subtask_list,
args.model,
torch_dtype,
)
for w in range(args.num_workers)
if episodes_per_worker[w]
]
for future in as_completed(futures):
try:
worker_sparse, worker_dense = future.result()
sparse_annotations.update(worker_sparse)
if dense_mode and worker_dense:
dense_annotations.update(worker_dense)
save_annotations_to_dataset(dataset.root, sparse_annotations, fps, prefix="sparse")
if dense_mode:
save_annotations_to_dataset(dataset.root, dense_annotations, fps, prefix="dense")
except Exception as e:
raise RuntimeError(f"Worker failed: {e}") from e
else:
# Sequential processing
sparse_annotator = (
VideoAnnotator(sparse_subtask_list, args.model, args.device, torch_dtype)
if not auto_sparse and sparse_subtask_list
else None
)
dense_annotator = (
VideoAnnotator(
dense_subtask_list,
args.model,
args.device,
torch_dtype,
sparse_annotator.model if sparse_annotator else None,
sparse_annotator.processor if sparse_annotator else None,
)
if dense_mode
else None
)
for i, ep_idx in enumerate(episode_indices):
console.print(f"[cyan]Episode {ep_idx} ({i + 1}/{len(episode_indices)})[/cyan]")
if sparse_annotator:
_, sparse_ann, err = process_single_episode(
ep_idx, dataset.root, dataset.meta, video_key, fps, sparse_annotator, console
)
if sparse_ann:
sparse_annotations[ep_idx] = sparse_ann
save_annotations_to_dataset(dataset.root, sparse_annotations, fps, prefix="sparse")
elif err:
console.print(f"[red]Sparse failed: {err}[/red]")
if dense_annotator:
_, dense_ann, err = process_single_episode(
ep_idx, dataset.root, dataset.meta, video_key, fps, dense_annotator, console
)
if dense_ann:
dense_annotations[ep_idx] = dense_ann
save_annotations_to_dataset(dataset.root, dense_annotations, fps, prefix="dense")
elif err:
console.print(f"[red]Dense failed: {err}[/red]")
# Save temporal proportions
def save_proportions(annotations, prefix, is_auto=False):
props: dict[str, float] = {"task": 1.0} if is_auto else compute_temporal_proportions(annotations, fps)
path = dataset.root / "meta" / f"temporal_proportions_{prefix}.json"
path.parent.mkdir(parents=True, exist_ok=True)
with open(path, "w") as f:
json.dump(props, f, indent=2)
console.print(f"[green]Saved {prefix} temporal proportions[/green]")
save_proportions(sparse_annotations, "sparse", auto_sparse)
if dense_mode and dense_annotations:
save_proportions(dense_annotations, "dense")
console.print(
f"\n[bold green]Complete! {len(sparse_annotations)} sparse, {len(dense_annotations or {})} dense annotations[/bold green]"
)
if args.push_to_hub:
try:
dataset.push_to_hub(push_videos=True)
console.print(f"[green]Pushed to {args.output_repo_id or args.repo_id}[/green]")
except Exception as e:
console.print(f"[red]Push failed: {e}[/red]")
if __name__ == "__main__":
main()

1
examples/dataset/test.txt Normal file
View File

@@ -0,0 +1 @@
srun --time 12:00:00 --qos=high --gres=gpu:1 --mem=24G --partition=hopper-prod --container-image /fsx/michel_aractingi/docker_images/huggingface+lerobot-gpu+dev.sqsh --container-mounts /fsx/jade_choghari

44
examples/dataset/test_pgen_quick.sh Executable file
View File

@@ -0,0 +1,44 @@
#!/bin/bash
# Quick test to verify the fix for task_indices length mismatch
# This should now work correctly even with --num-samples < full dataset length
echo "Testing annotate_pgen.py with --num-samples=100 on full dataset..."
python examples/dataset/annotate_pgen.py \
--data-dir /fsx/jade_choghari/.cache/huggingface/lerobot/lerobot/svla_so101_pickplace \
--model Qwen/Qwen3-VL-30B-A3B-Instruct \
--num-samples 100 \
--sample-interval 1.0 \
--output-dir /fsx/jade_choghari/outputs/pgen_test_fixed
if [ $? -eq 0 ]; then
echo "✓ SUCCESS: Script completed without errors!"
echo ""
echo "Verifying output..."
# Check that all frames have task_index_high_level
python -c "
from lerobot.datasets.lerobot_dataset import LeRobotDataset
import numpy as np
ds = LeRobotDataset(repo_id='local_test', root='/fsx/jade_choghari/outputs/pgen_test_fixed')
print(f'Dataset has {len(ds)} frames')
print(f'Features: {list(ds.features.keys())}')
# Check that task_index_high_level exists
assert 'task_index_high_level' in ds.features, 'task_index_high_level not in features!'
# Sample some frames
for idx in [0, 50, 99, 100, 500, 1000, 11938]:
if idx < len(ds):
frame = ds[idx]
task_idx = frame['task_index_high_level'].item()
print(f'Frame {idx}: task_index_high_level = {task_idx}')
print('✓ All checks passed!')
"
else
echo "✗ FAILED: Script exited with error code $?"
fi

72
examples/lekiwi/evaluate.py
View File

@@ -33,55 +33,57 @@ TASK_DESCRIPTION = "My task description"
HF_MODEL_ID = "<hf_username>/<model_repo_id>"
HF_DATASET_ID = "<hf_username>/<eval_dataset_repo_id>"
# Create the robot configuration & robot
robot_config = LeKiwiClientConfig(remote_ip="172.18.134.136", id="lekiwi")
robot = LeKiwiClient(robot_config)
def main():
# Create the robot configuration & robot
robot_config = LeKiwiClientConfig(remote_ip="172.18.134.136", id="lekiwi")
# Create policy
policy = ACTPolicy.from_pretrained(HF_MODEL_ID)
robot = LeKiwiClient(robot_config)
# Configure the dataset features
action_features = hw_to_dataset_features(robot.action_features, ACTION)
obs_features = hw_to_dataset_features(robot.observation_features, OBS_STR)
dataset_features = {**action_features, **obs_features}
# Create policy
policy = ACTPolicy.from_pretrained(HF_MODEL_ID)
# Create the dataset
dataset = LeRobotDataset.create(
# Configure the dataset features
action_features = hw_to_dataset_features(robot.action_features, ACTION)
obs_features = hw_to_dataset_features(robot.observation_features, OBS_STR)
dataset_features = {**action_features, **obs_features}
# Create the dataset
dataset = LeRobotDataset.create(
repo_id=HF_DATASET_ID,
fps=FPS,
features=dataset_features,
robot_type=robot.name,
use_videos=True,
image_writer_threads=4,
)
)
# Build Policy Processors
preprocessor, postprocessor = make_pre_post_processors(
# Build Policy Processors
preprocessor, postprocessor = make_pre_post_processors(
policy_cfg=policy,
pretrained_path=HF_MODEL_ID,
dataset_stats=dataset.meta.stats,
# The inference device is automatically set to match the detected hardware, overriding any previous device settings from training to ensure compatibility.
preprocessor_overrides={"device_processor": {"device": str(policy.config.device)}},
)
)
# Connect the robot
# To connect you already should have this script running on LeKiwi: `python -m lerobot.robots.lekiwi.lekiwi_host --robot.id=my_awesome_kiwi`
robot.connect()
# Connect the robot
# To connect you already should have this script running on LeKiwi: `python -m lerobot.robots.lekiwi.lekiwi_host --robot.id=my_awesome_kiwi`
robot.connect()
# TODO(Steven): Update this example to use pipelines
teleop_action_processor, robot_action_processor, robot_observation_processor = make_default_processors()
# TODO(Steven): Update this example to use pipelines
teleop_action_processor, robot_action_processor, robot_observation_processor = make_default_processors()
# Initialize the keyboard listener and rerun visualization
listener, events = init_keyboard_listener()
init_rerun(session_name="lekiwi_evaluate")
# Initialize the keyboard listener and rerun visualization
listener, events = init_keyboard_listener()
init_rerun(session_name="lekiwi_evaluate")
if not robot.is_connected:
if not robot.is_connected:
raise ValueError("Robot is not connected!")
print("Starting evaluate loop...")
recorded_episodes = 0
while recorded_episodes < NUM_EPISODES and not events["stop_recording"]:
print("Starting evaluate loop...")
recorded_episodes = 0
while recorded_episodes < NUM_EPISODES and not events["stop_recording"]:
log_say(f"Running inference, recording eval episode {recorded_episodes} of {NUM_EPISODES}")
# Main record loop
@@ -129,10 +131,14 @@ while recorded_episodes < NUM_EPISODES and not events["stop_recording"]:
dataset.save_episode()
recorded_episodes += 1
# Clean up
log_say("Stop recording")
robot.disconnect()
listener.stop()
# Clean up
log_say("Stop recording")
robot.disconnect()
listener.stop()
dataset.finalize()
dataset.push_to_hub()
dataset.finalize()
dataset.push_to_hub()
if __name__ == "__main__":
main()

80
examples/lekiwi/record.py
View File

@@ -34,50 +34,52 @@ RESET_TIME_SEC = 10
TASK_DESCRIPTION = "My task description"
HF_REPO_ID = "<hf_username>/<dataset_repo_id>"
# Create the robot and teleoperator configurations
robot_config = LeKiwiClientConfig(remote_ip="172.18.134.136", id="lekiwi")
leader_arm_config = SO100LeaderConfig(port="/dev/tty.usbmodem585A0077581", id="my_awesome_leader_arm")
keyboard_config = KeyboardTeleopConfig()
# Initialize the robot and teleoperator
robot = LeKiwiClient(robot_config)
leader_arm = SO100Leader(leader_arm_config)
keyboard = KeyboardTeleop(keyboard_config)
def main():
# Create the robot and teleoperator configurations
robot_config = LeKiwiClientConfig(remote_ip="172.18.134.136", id="lekiwi")
leader_arm_config = SO100LeaderConfig(port="/dev/tty.usbmodem585A0077581", id="my_awesome_leader_arm")
keyboard_config = KeyboardTeleopConfig()
# TODO(Steven): Update this example to use pipelines
teleop_action_processor, robot_action_processor, robot_observation_processor = make_default_processors()
# Initialize the robot and teleoperator
robot = LeKiwiClient(robot_config)
leader_arm = SO100Leader(leader_arm_config)
keyboard = KeyboardTeleop(keyboard_config)
# Configure the dataset features
action_features = hw_to_dataset_features(robot.action_features, ACTION)
obs_features = hw_to_dataset_features(robot.observation_features, OBS_STR)
dataset_features = {**action_features, **obs_features}
# TODO(Steven): Update this example to use pipelines
teleop_action_processor, robot_action_processor, robot_observation_processor = make_default_processors()
# Create the dataset
dataset = LeRobotDataset.create(
# Configure the dataset features
action_features = hw_to_dataset_features(robot.action_features, ACTION)
obs_features = hw_to_dataset_features(robot.observation_features, OBS_STR)
dataset_features = {**action_features, **obs_features}
# Create the dataset
dataset = LeRobotDataset.create(
repo_id=HF_REPO_ID,
fps=FPS,
features=dataset_features,
robot_type=robot.name,
use_videos=True,
image_writer_threads=4,
)
)
# Connect the robot and teleoperator
# To connect you already should have this script running on LeKiwi: `python -m lerobot.robots.lekiwi.lekiwi_host --robot.id=my_awesome_kiwi`
robot.connect()
leader_arm.connect()
keyboard.connect()
# Connect the robot and teleoperator
# To connect you already should have this script running on LeKiwi: `python -m lerobot.robots.lekiwi.lekiwi_host --robot.id=my_awesome_kiwi`
robot.connect()
leader_arm.connect()
keyboard.connect()
# Initialize the keyboard listener and rerun visualization
listener, events = init_keyboard_listener()
init_rerun(session_name="lekiwi_record")
# Initialize the keyboard listener and rerun visualization
listener, events = init_keyboard_listener()
init_rerun(session_name="lekiwi_record")
if not robot.is_connected or not leader_arm.is_connected or not keyboard.is_connected:
if not robot.is_connected or not leader_arm.is_connected or not keyboard.is_connected:
raise ValueError("Robot or teleop is not connected!")
print("Starting record loop...")
recorded_episodes = 0
while recorded_episodes < NUM_EPISODES and not events["stop_recording"]:
print("Starting record loop...")
recorded_episodes = 0
while recorded_episodes < NUM_EPISODES and not events["stop_recording"]:
log_say(f"Recording episode {recorded_episodes}")
# Main record loop
@@ -124,12 +126,16 @@ while recorded_episodes < NUM_EPISODES and not events["stop_recording"]:
dataset.save_episode()
recorded_episodes += 1
# Clean up
log_say("Stop recording")
robot.disconnect()
leader_arm.disconnect()
keyboard.disconnect()
listener.stop()
# Clean up
log_say("Stop recording")
robot.disconnect()
leader_arm.disconnect()
keyboard.disconnect()
listener.stop()
dataset.finalize()
dataset.push_to_hub()
dataset.finalize()
dataset.push_to_hub()
if __name__ == "__main__":
main()

42
examples/lekiwi/replay.py
View File

@@ -20,32 +20,34 @@ from lerobot.datasets.lerobot_dataset import LeRobotDataset
from lerobot.robots.lekiwi.config_lekiwi import LeKiwiClientConfig
from lerobot.robots.lekiwi.lekiwi_client import LeKiwiClient
from lerobot.utils.constants import ACTION
from lerobot.utils.robot_utils import busy_wait
from lerobot.utils.robot_utils import precise_sleep
from lerobot.utils.utils import log_say
EPISODE_IDX = 0
# Initialize the robot config
robot_config = LeKiwiClientConfig(remote_ip="172.18.134.136", id="lekiwi")
# Initialize the robot
robot = LeKiwiClient(robot_config)
def main():
# Initialize the robot config
robot_config = LeKiwiClientConfig(remote_ip="172.18.134.136", id="lekiwi")
# Fetch the dataset to replay
dataset = LeRobotDataset("<hf_username>/<dataset_repo_id>", episodes=[EPISODE_IDX])
# Filter dataset to only include frames from the specified episode since episodes are chunked in dataset V3.0
episode_frames = dataset.hf_dataset.filter(lambda x: x["episode_index"] == EPISODE_IDX)
actions = episode_frames.select_columns(ACTION)
# Initialize the robot
robot = LeKiwiClient(robot_config)
# Connect to the robot
robot.connect()
# Fetch the dataset to replay
dataset = LeRobotDataset("<hf_username>/<dataset_repo_id>", episodes=[EPISODE_IDX])
# Filter dataset to only include frames from the specified episode since episodes are chunked in dataset V3.0
episode_frames = dataset.hf_dataset.filter(lambda x: x["episode_index"] == EPISODE_IDX)
actions = episode_frames.select_columns(ACTION)
if not robot.is_connected:
# Connect to the robot
robot.connect()
if not robot.is_connected:
raise ValueError("Robot is not connected!")
print("Starting replay loop...")
log_say(f"Replaying episode {EPISODE_IDX}")
for idx in range(len(episode_frames)):
print("Starting replay loop...")
log_say(f"Replaying episode {EPISODE_IDX}")
for idx in range(len(episode_frames)):
t0 = time.perf_counter()
# Get recorded action from dataset
@@ -56,6 +58,10 @@ for idx in range(len(episode_frames)):
# Send action to robot
_ = robot.send_action(action)
busy_wait(max(1.0 / dataset.fps - (time.perf_counter() - t0), 0.0))
precise_sleep(max(1.0 / dataset.fps - (time.perf_counter() - t0), 0.0))
robot.disconnect()
robot.disconnect()
if __name__ == "__main__":
main()

46
examples/lekiwi/teleoperate.py
View File

@@ -19,35 +19,37 @@ import time
from lerobot.robots.lekiwi import LeKiwiClient, LeKiwiClientConfig
from lerobot.teleoperators.keyboard.teleop_keyboard import KeyboardTeleop, KeyboardTeleopConfig
from lerobot.teleoperators.so100_leader import SO100Leader, SO100LeaderConfig
from lerobot.utils.robot_utils import busy_wait
from lerobot.utils.robot_utils import precise_sleep
from lerobot.utils.visualization_utils import init_rerun, log_rerun_data
FPS = 30
# Create the robot and teleoperator configurations
robot_config = LeKiwiClientConfig(remote_ip="172.18.134.136", id="my_lekiwi")
teleop_arm_config = SO100LeaderConfig(port="/dev/tty.usbmodem585A0077581", id="my_awesome_leader_arm")
keyboard_config = KeyboardTeleopConfig(id="my_laptop_keyboard")
# Initialize the robot and teleoperator
robot = LeKiwiClient(robot_config)
leader_arm = SO100Leader(teleop_arm_config)
keyboard = KeyboardTeleop(keyboard_config)
def main():
# Create the robot and teleoperator configurations
robot_config = LeKiwiClientConfig(remote_ip="172.18.134.136", id="my_lekiwi")
teleop_arm_config = SO100LeaderConfig(port="/dev/tty.usbmodem585A0077581", id="my_awesome_leader_arm")
keyboard_config = KeyboardTeleopConfig(id="my_laptop_keyboard")
# Connect to the robot and teleoperator
# To connect you already should have this script running on LeKiwi: `python -m lerobot.robots.lekiwi.lekiwi_host --robot.id=my_awesome_kiwi`
robot.connect()
leader_arm.connect()
keyboard.connect()
# Initialize the robot and teleoperator
robot = LeKiwiClient(robot_config)
leader_arm = SO100Leader(teleop_arm_config)
keyboard = KeyboardTeleop(keyboard_config)
# Init rerun viewer
init_rerun(session_name="lekiwi_teleop")
# Connect to the robot and teleoperator
# To connect you already should have this script running on LeKiwi: `python -m lerobot.robots.lekiwi.lekiwi_host --robot.id=my_awesome_kiwi`
robot.connect()
leader_arm.connect()
keyboard.connect()
if not robot.is_connected or not leader_arm.is_connected or not keyboard.is_connected:
# Init rerun viewer
init_rerun(session_name="lekiwi_teleop")
if not robot.is_connected or not leader_arm.is_connected or not keyboard.is_connected:
raise ValueError("Robot or teleop is not connected!")
print("Starting teleop loop...")
while True:
print("Starting teleop loop...")
while True:
t0 = time.perf_counter()
# Get robot observation
@@ -69,4 +71,8 @@ while True:
# Visualize
log_rerun_data(observation=observation, action=action)
busy_wait(max(1.0 / FPS - (time.perf_counter() - t0), 0.0))
precise_sleep(max(1.0 / FPS - (time.perf_counter() - t0), 0.0))
if __name__ == "__main__":
main()

84
examples/phone_to_so100/evaluate.py
View File

@@ -52,29 +52,31 @@ TASK_DESCRIPTION = "My task description"
HF_MODEL_ID = "<hf_username>/<model_repo_id>"
HF_DATASET_ID = "<hf_username>/<dataset_repo_id>"
# Create the robot configuration & robot
camera_config = {"front": OpenCVCameraConfig(index_or_path=0, width=640, height=480, fps=FPS)}
robot_config = SO100FollowerConfig(
def main():
# Create the robot configuration & robot
camera_config = {"front": OpenCVCameraConfig(index_or_path=0, width=640, height=480, fps=FPS)}
robot_config = SO100FollowerConfig(
port="/dev/tty.usbmodem58760434471",
id="my_awesome_follower_arm",
cameras=camera_config,
use_degrees=True,
)
)
robot = SO100Follower(robot_config)
robot = SO100Follower(robot_config)
# Create policy
policy = ACTPolicy.from_pretrained(HF_MODEL_ID)
# Create policy
policy = ACTPolicy.from_pretrained(HF_MODEL_ID)
# NOTE: It is highly recommended to use the urdf in the SO-ARM100 repo: https://github.com/TheRobotStudio/SO-ARM100/blob/main/Simulation/SO101/so101_new_calib.urdf
kinematics_solver = RobotKinematics(
# NOTE: It is highly recommended to use the urdf in the SO-ARM100 repo: https://github.com/TheRobotStudio/SO-ARM100/blob/main/Simulation/SO101/so101_new_calib.urdf
kinematics_solver = RobotKinematics(
urdf_path="./SO101/so101_new_calib.urdf",
target_frame_name="gripper_frame_link",
joint_names=list(robot.bus.motors.keys()),
)
)
# Build pipeline to convert EE action to joints action
robot_ee_to_joints_processor = RobotProcessorPipeline[tuple[RobotAction, RobotObservation], RobotAction](
# Build pipeline to convert EE action to joints action
robot_ee_to_joints_processor = RobotProcessorPipeline[tuple[RobotAction, RobotObservation], RobotAction](
steps=[
InverseKinematicsEEToJoints(
kinematics=kinematics_solver,
@@ -84,19 +86,21 @@ robot_ee_to_joints_processor = RobotProcessorPipeline[tuple[RobotAction, RobotOb
],
to_transition=robot_action_observation_to_transition,
to_output=transition_to_robot_action,
)
)
# Build pipeline to convert joints observation to EE observation
robot_joints_to_ee_pose_processor = RobotProcessorPipeline[RobotObservation, RobotObservation](
# Build pipeline to convert joints observation to EE observation
robot_joints_to_ee_pose_processor = RobotProcessorPipeline[RobotObservation, RobotObservation](
steps=[
ForwardKinematicsJointsToEE(kinematics=kinematics_solver, motor_names=list(robot.bus.motors.keys()))
ForwardKinematicsJointsToEE(
kinematics=kinematics_solver, motor_names=list(robot.bus.motors.keys())
)
],
to_transition=observation_to_transition,
to_output=transition_to_observation,
)
)
# Create the dataset
dataset = LeRobotDataset.create(
# Create the dataset
dataset = LeRobotDataset.create(
repo_id=HF_DATASET_ID,
fps=FPS,
features=combine_feature_dicts(
@@ -121,30 +125,30 @@ dataset = LeRobotDataset.create(
robot_type=robot.name,
use_videos=True,
image_writer_threads=4,
)
)
# Build Policy Processors
preprocessor, postprocessor = make_pre_post_processors(
# Build Policy Processors
preprocessor, postprocessor = make_pre_post_processors(
policy_cfg=policy,
pretrained_path=HF_MODEL_ID,
dataset_stats=dataset.meta.stats,
# The inference device is automatically set to match the detected hardware, overriding any previous device settings from training to ensure compatibility.
preprocessor_overrides={"device_processor": {"device": str(policy.config.device)}},
)
)
# Connect the robot
robot.connect()
# Connect the robot
robot.connect()
# Initialize the keyboard listener and rerun visualization
listener, events = init_keyboard_listener()
init_rerun(session_name="phone_so100_evaluate")
# Initialize the keyboard listener and rerun visualization
listener, events = init_keyboard_listener()
init_rerun(session_name="phone_so100_evaluate")
if not robot.is_connected:
if not robot.is_connected:
raise ValueError("Robot is not connected!")
print("Starting evaluate loop...")
episode_idx = 0
for episode_idx in range(NUM_EPISODES):
print("Starting evaluate loop...")
episode_idx = 0
for episode_idx in range(NUM_EPISODES):
log_say(f"Running inference, recording eval episode {episode_idx + 1} of {NUM_EPISODES}")
# Main record loop
@@ -190,10 +194,14 @@ for episode_idx in range(NUM_EPISODES):
dataset.save_episode()
episode_idx += 1
# Clean up
log_say("Stop recording")
robot.disconnect()
listener.stop()
# Clean up
log_say("Stop recording")
robot.disconnect()
listener.stop()
dataset.finalize()
dataset.push_to_hub()
dataset.finalize()
dataset.push_to_hub()
if __name__ == "__main__":
main()

93
examples/phone_to_so100/record.py
View File

@@ -50,29 +50,33 @@ RESET_TIME_SEC = 30
TASK_DESCRIPTION = "My task description"
HF_REPO_ID = "<hf_username>/<dataset_repo_id>"
# Create the robot and teleoperator configurations
camera_config = {"front": OpenCVCameraConfig(index_or_path=0, width=640, height=480, fps=FPS)}
robot_config = SO100FollowerConfig(
def main():
# Create the robot and teleoperator configurations
camera_config = {"front": OpenCVCameraConfig(index_or_path=0, width=640, height=480, fps=FPS)}
robot_config = SO100FollowerConfig(
port="/dev/tty.usbmodem5A460814411",
id="my_awesome_follower_arm",
cameras=camera_config,
use_degrees=True,
)
teleop_config = PhoneConfig(phone_os=PhoneOS.IOS) # or PhoneOS.ANDROID
)
teleop_config = PhoneConfig(phone_os=PhoneOS.IOS) # or PhoneOS.ANDROID
# Initialize the robot and teleoperator
robot = SO100Follower(robot_config)
phone = Phone(teleop_config)
# Initialize the robot and teleoperator
robot = SO100Follower(robot_config)
phone = Phone(teleop_config)
# NOTE: It is highly recommended to use the urdf in the SO-ARM100 repo: https://github.com/TheRobotStudio/SO-ARM100/blob/main/Simulation/SO101/so101_new_calib.urdf
kinematics_solver = RobotKinematics(
# NOTE: It is highly recommended to use the urdf in the SO-ARM100 repo: https://github.com/TheRobotStudio/SO-ARM100/blob/main/Simulation/SO101/so101_new_calib.urdf
kinematics_solver = RobotKinematics(
urdf_path="./SO101/so101_new_calib.urdf",
target_frame_name="gripper_frame_link",
joint_names=list(robot.bus.motors.keys()),
)
)
# Build pipeline to convert phone action to EE action
phone_to_robot_ee_pose_processor = RobotProcessorPipeline[tuple[RobotAction, RobotObservation], RobotAction](
# Build pipeline to convert phone action to EE action
phone_to_robot_ee_pose_processor = RobotProcessorPipeline[
tuple[RobotAction, RobotObservation], RobotAction
](
steps=[
MapPhoneActionToRobotAction(platform=teleop_config.phone_os),
EEReferenceAndDelta(
@@ -89,10 +93,10 @@ phone_to_robot_ee_pose_processor = RobotProcessorPipeline[tuple[RobotAction, Rob
],
to_transition=robot_action_observation_to_transition,
to_output=transition_to_robot_action,
)
)
# Build pipeline to convert EE action to joints action
robot_ee_to_joints_processor = RobotProcessorPipeline[tuple[RobotAction, RobotObservation], RobotAction](
# Build pipeline to convert EE action to joints action
robot_ee_to_joints_processor = RobotProcessorPipeline[tuple[RobotAction, RobotObservation], RobotAction](
steps=[
InverseKinematicsEEToJoints(
kinematics=kinematics_solver,
@@ -102,19 +106,21 @@ robot_ee_to_joints_processor = RobotProcessorPipeline[tuple[RobotAction, RobotOb
],
to_transition=robot_action_observation_to_transition,
to_output=transition_to_robot_action,
)
)
# Build pipeline to convert joint observation to EE observation
robot_joints_to_ee_pose = RobotProcessorPipeline[RobotObservation, RobotObservation](
# Build pipeline to convert joint observation to EE observation
robot_joints_to_ee_pose = RobotProcessorPipeline[RobotObservation, RobotObservation](
steps=[
ForwardKinematicsJointsToEE(kinematics=kinematics_solver, motor_names=list(robot.bus.motors.keys()))
ForwardKinematicsJointsToEE(
kinematics=kinematics_solver, motor_names=list(robot.bus.motors.keys())
)
],
to_transition=observation_to_transition,
to_output=transition_to_observation,
)
)
# Create the dataset
dataset = LeRobotDataset.create(
# Create the dataset
dataset = LeRobotDataset.create(
repo_id=HF_REPO_ID,
fps=FPS,
features=combine_feature_dicts(
@@ -134,23 +140,22 @@ dataset = LeRobotDataset.create(
robot_type=robot.name,
use_videos=True,
image_writer_threads=4,
)
)
# Connect the robot and teleoperator
robot.connect()
phone.connect()
# Connect the robot and teleoperator
robot.connect()
phone.connect()
# Initialize the keyboard listener and rerun visualization
listener, events = init_keyboard_listener()
init_rerun(session_name="phone_so100_record")
# Initialize the keyboard listener and rerun visualization
listener, events = init_keyboard_listener()
init_rerun(session_name="phone_so100_record")
if not robot.is_connected or not phone.is_connected:
if not robot.is_connected or not phone.is_connected:
raise ValueError("Robot or teleop is not connected!")
print("Starting record loop. Move your phone to teleoperate the robot...")
episode_idx = 0
while episode_idx < NUM_EPISODES and not events["stop_recording"]:
print("Starting record loop. Move your phone to teleoperate the robot...")
episode_idx = 0
while episode_idx < NUM_EPISODES and not events["stop_recording"]:
log_say(f"Recording episode {episode_idx + 1} of {NUM_EPISODES}")
# Main record loop
@@ -195,11 +200,15 @@ while episode_idx < NUM_EPISODES and not events["stop_recording"]:
dataset.save_episode()
episode_idx += 1
# Clean up
log_say("Stop recording")
robot.disconnect()
phone.disconnect()
listener.stop()
# Clean up
log_say("Stop recording")
robot.disconnect()
phone.disconnect()
listener.stop()
dataset.finalize()
dataset.push_to_hub()
dataset.finalize()
dataset.push_to_hub()
if __name__ == "__main__":
main()

58
examples/phone_to_so100/replay.py
View File

@@ -29,29 +29,31 @@ from lerobot.robots.so100_follower.robot_kinematic_processor import (
)
from lerobot.robots.so100_follower.so100_follower import SO100Follower
from lerobot.utils.constants import ACTION
from lerobot.utils.robot_utils import busy_wait
from lerobot.utils.robot_utils import precise_sleep
from lerobot.utils.utils import log_say
EPISODE_IDX = 0
HF_REPO_ID = "<hf_username>/<dataset_repo_id>"
# Initialize the robot config
robot_config = SO100FollowerConfig(
def main():
# Initialize the robot config
robot_config = SO100FollowerConfig(
port="/dev/tty.usbmodem5A460814411", id="my_awesome_follower_arm", use_degrees=True
)
)
# Initialize the robot
robot = SO100Follower(robot_config)
# Initialize the robot
robot = SO100Follower(robot_config)
# NOTE: It is highly recommended to use the urdf in the SO-ARM100 repo: https://github.com/TheRobotStudio/SO-ARM100/blob/main/Simulation/SO101/so101_new_calib.urdf
kinematics_solver = RobotKinematics(
# NOTE: It is highly recommended to use the urdf in the SO-ARM100 repo: https://github.com/TheRobotStudio/SO-ARM100/blob/main/Simulation/SO101/so101_new_calib.urdf
kinematics_solver = RobotKinematics(
urdf_path="./SO101/so101_new_calib.urdf",
target_frame_name="gripper_frame_link",
joint_names=list(robot.bus.motors.keys()),
)
)
# Build pipeline to convert EE action to joints action
robot_ee_to_joints_processor = RobotProcessorPipeline[tuple[RobotAction, RobotObservation], RobotAction](
# Build pipeline to convert EE action to joints action
robot_ee_to_joints_processor = RobotProcessorPipeline[tuple[RobotAction, RobotObservation], RobotAction](
steps=[
InverseKinematicsEEToJoints(
kinematics=kinematics_solver,
@@ -61,23 +63,23 @@ robot_ee_to_joints_processor = RobotProcessorPipeline[tuple[RobotAction, RobotOb
],
to_transition=robot_action_observation_to_transition,
to_output=transition_to_robot_action,
)
)
# Fetch the dataset to replay
dataset = LeRobotDataset(HF_REPO_ID, episodes=[EPISODE_IDX])
# Filter dataset to only include frames from the specified episode since episodes are chunked in dataset V3.0
episode_frames = dataset.hf_dataset.filter(lambda x: x["episode_index"] == EPISODE_IDX)
actions = episode_frames.select_columns(ACTION)
# Fetch the dataset to replay
dataset = LeRobotDataset(HF_REPO_ID, episodes=[EPISODE_IDX])
# Filter dataset to only include frames from the specified episode since episodes are chunked in dataset V3.0
episode_frames = dataset.hf_dataset.filter(lambda x: x["episode_index"] == EPISODE_IDX)
actions = episode_frames.select_columns(ACTION)
# Connect to the robot
robot.connect()
# Connect to the robot
robot.connect()
if not robot.is_connected:
if not robot.is_connected:
raise ValueError("Robot is not connected!")
print("Starting replay loop...")
log_say(f"Replaying episode {EPISODE_IDX}")
for idx in range(len(episode_frames)):
print("Starting replay loop...")
log_say(f"Replaying episode {EPISODE_IDX}")
for idx in range(len(episode_frames)):
t0 = time.perf_counter()
# Get recorded action from dataset
@@ -94,7 +96,11 @@ for idx in range(len(episode_frames)):
# Send action to robot
_ = robot.send_action(joint_action)
busy_wait(1.0 / dataset.fps - (time.perf_counter() - t0))
precise_sleep(1.0 / dataset.fps - (time.perf_counter() - t0))
# Clean up
robot.disconnect()
# Clean up
robot.disconnect()
if __name__ == "__main__":
main()

54
examples/phone_to_so100/teleoperate.py
View File

@@ -32,30 +32,34 @@ from lerobot.robots.so100_follower.so100_follower import SO100Follower
from lerobot.teleoperators.phone.config_phone import PhoneConfig, PhoneOS
from lerobot.teleoperators.phone.phone_processor import MapPhoneActionToRobotAction
from lerobot.teleoperators.phone.teleop_phone import Phone
from lerobot.utils.robot_utils import busy_wait
from lerobot.utils.robot_utils import precise_sleep
from lerobot.utils.visualization_utils import init_rerun, log_rerun_data
FPS = 30
# Initialize the robot and teleoperator
robot_config = SO100FollowerConfig(
def main():
# Initialize the robot and teleoperator
robot_config = SO100FollowerConfig(
port="/dev/tty.usbmodem5A460814411", id="my_awesome_follower_arm", use_degrees=True
)
teleop_config = PhoneConfig(phone_os=PhoneOS.IOS) # or PhoneOS.ANDROID
)
teleop_config = PhoneConfig(phone_os=PhoneOS.IOS) # or PhoneOS.ANDROID
# Initialize the robot and teleoperator
robot = SO100Follower(robot_config)
teleop_device = Phone(teleop_config)
# Initialize the robot and teleoperator
robot = SO100Follower(robot_config)
teleop_device = Phone(teleop_config)
# NOTE: It is highly recommended to use the urdf in the SO-ARM100 repo: https://github.com/TheRobotStudio/SO-ARM100/blob/main/Simulation/SO101/so101_new_calib.urdf
kinematics_solver = RobotKinematics(
# NOTE: It is highly recommended to use the urdf in the SO-ARM100 repo: https://github.com/TheRobotStudio/SO-ARM100/blob/main/Simulation/SO101/so101_new_calib.urdf
kinematics_solver = RobotKinematics(
urdf_path="./SO101/so101_new_calib.urdf",
target_frame_name="gripper_frame_link",
joint_names=list(robot.bus.motors.keys()),
)
)
# Build pipeline to convert phone action to ee pose action to joint action
phone_to_robot_joints_processor = RobotProcessorPipeline[tuple[RobotAction, RobotObservation], RobotAction](
# Build pipeline to convert phone action to ee pose action to joint action
phone_to_robot_joints_processor = RobotProcessorPipeline[
tuple[RobotAction, RobotObservation], RobotAction
](
steps=[
MapPhoneActionToRobotAction(platform=teleop_config.phone_os),
EEReferenceAndDelta(
@@ -79,20 +83,20 @@ phone_to_robot_joints_processor = RobotProcessorPipeline[tuple[RobotAction, Robo
],
to_transition=robot_action_observation_to_transition,
to_output=transition_to_robot_action,
)
)
# Connect to the robot and teleoperator
robot.connect()
teleop_device.connect()
# Connect to the robot and teleoperator
robot.connect()
teleop_device.connect()
# Init rerun viewer
init_rerun(session_name="phone_so100_teleop")
# Init rerun viewer
init_rerun(session_name="phone_so100_teleop")
if not robot.is_connected or not teleop_device.is_connected:
if not robot.is_connected or not teleop_device.is_connected:
raise ValueError("Robot or teleop is not connected!")
print("Starting teleop loop. Move your phone to teleoperate the robot...")
while True:
print("Starting teleop loop. Move your phone to teleoperate the robot...")
while True:
t0 = time.perf_counter()
# Get robot observation
@@ -110,4 +114,8 @@ while True:
# Visualize
log_rerun_data(observation=phone_obs, action=joint_action)
busy_wait(max(1.0 / FPS - (time.perf_counter() - t0), 0.0))
precise_sleep(max(1.0 / FPS - (time.perf_counter() - t0), 0.0))
if __name__ == "__main__":
main()

85
examples/so100_to_so100_EE/evaluate.py
View File

@@ -52,29 +52,31 @@ TASK_DESCRIPTION = "My task description"
HF_MODEL_ID = "<hf_username>/<model_repo_id>"
HF_DATASET_ID = "<hf_username>/<dataset_repo_id>"
# Create the robot configuration & robot
camera_config = {"front": OpenCVCameraConfig(index_or_path=0, width=640, height=480, fps=FPS)}
robot_config = SO100FollowerConfig(
def main():
# Create the robot configuration & robot
camera_config = {"front": OpenCVCameraConfig(index_or_path=0, width=640, height=480, fps=FPS)}
robot_config = SO100FollowerConfig(
port="/dev/tty.usbmodem5A460814411",
id="my_awesome_follower_arm",
cameras=camera_config,
use_degrees=True,
)
)
robot = SO100Follower(robot_config)
robot = SO100Follower(robot_config)
# Create policy
policy = ACTPolicy.from_pretrained(HF_MODEL_ID)
# Create policy
policy = ACTPolicy.from_pretrained(HF_MODEL_ID)
# NOTE: It is highly recommended to use the urdf in the SO-ARM100 repo: https://github.com/TheRobotStudio/SO-ARM100/blob/main/Simulation/SO101/so101_new_calib.urdf
kinematics_solver = RobotKinematics(
# NOTE: It is highly recommended to use the urdf in the SO-ARM100 repo: https://github.com/TheRobotStudio/SO-ARM100/blob/main/Simulation/SO101/so101_new_calib.urdf
kinematics_solver = RobotKinematics(
urdf_path="./SO101/so101_new_calib.urdf",
target_frame_name="gripper_frame_link",
joint_names=list(robot.bus.motors.keys()),
)
)
# Build pipeline to convert EE action to joints action
robot_ee_to_joints_processor = RobotProcessorPipeline[tuple[RobotAction, RobotObservation], RobotAction](
# Build pipeline to convert EE action to joints action
robot_ee_to_joints_processor = RobotProcessorPipeline[tuple[RobotAction, RobotObservation], RobotAction](
steps=[
InverseKinematicsEEToJoints(
kinematics=kinematics_solver,
@@ -84,20 +86,21 @@ robot_ee_to_joints_processor = RobotProcessorPipeline[tuple[RobotAction, RobotOb
],
to_transition=robot_action_observation_to_transition,
to_output=transition_to_robot_action,
)
)
# Build pipeline to convert joints observation to EE observation
robot_joints_to_ee_pose_processor = RobotProcessorPipeline[RobotObservation, RobotObservation](
# Build pipeline to convert joints observation to EE observation
robot_joints_to_ee_pose_processor = RobotProcessorPipeline[RobotObservation, RobotObservation](
steps=[
ForwardKinematicsJointsToEE(kinematics=kinematics_solver, motor_names=list(robot.bus.motors.keys()))
ForwardKinematicsJointsToEE(
kinematics=kinematics_solver, motor_names=list(robot.bus.motors.keys())
)
],
to_transition=observation_to_transition,
to_output=transition_to_observation,
)
)
# Create the dataset
dataset = LeRobotDataset.create(
# Create the dataset
dataset = LeRobotDataset.create(
repo_id=HF_DATASET_ID,
fps=FPS,
features=combine_feature_dicts(
@@ -122,30 +125,30 @@ dataset = LeRobotDataset.create(
robot_type=robot.name,
use_videos=True,
image_writer_threads=4,
)
)
# Build Policy Processors
preprocessor, postprocessor = make_pre_post_processors(
# Build Policy Processors
preprocessor, postprocessor = make_pre_post_processors(
policy_cfg=policy,
pretrained_path=HF_MODEL_ID,
dataset_stats=dataset.meta.stats,
# The inference device is automatically set to match the detected hardware, overriding any previous device settings from training to ensure compatibility.
preprocessor_overrides={"device_processor": {"device": str(policy.config.device)}},
)
)
# Connect the robot and teleoperator
robot.connect()
# Connect the robot and teleoperator
robot.connect()
# Initialize the keyboard listener and rerun visualization
listener, events = init_keyboard_listener()
init_rerun(session_name="so100_so100_evaluate")
# Initialize the keyboard listener and rerun visualization
listener, events = init_keyboard_listener()
init_rerun(session_name="so100_so100_evaluate")
if not robot.is_connected:
if not robot.is_connected:
raise ValueError("Robot is not connected!")
print("Starting evaluate loop...")
episode_idx = 0
for episode_idx in range(NUM_EPISODES):
print("Starting evaluate loop...")
episode_idx = 0
for episode_idx in range(NUM_EPISODES):
log_say(f"Running inference, recording eval episode {episode_idx + 1} of {NUM_EPISODES}")
# Main record loop
@@ -191,10 +194,14 @@ for episode_idx in range(NUM_EPISODES):
dataset.save_episode()
episode_idx += 1
# Clean up
log_say("Stop recording")
robot.disconnect()
listener.stop()
# Clean up
log_say("Stop recording")
robot.disconnect()
listener.stop()
dataset.finalize()
dataset.push_to_hub()
dataset.finalize()
dataset.push_to_hub()
if __name__ == "__main__":
main()

98
examples/so100_to_so100_EE/record.py
View File

@@ -48,33 +48,38 @@ RESET_TIME_SEC = 30
TASK_DESCRIPTION = "My task description"
HF_REPO_ID = "<hf_username>/<dataset_repo_id>"
# Create the robot and teleoperator configurations
camera_config = {"front": OpenCVCameraConfig(index_or_path=0, width=640, height=480, fps=FPS)}
follower_config = SO100FollowerConfig(
port="/dev/tty.usbmodem5A460814411", id="my_awesome_follower_arm", cameras=camera_config, use_degrees=True
)
leader_config = SO100LeaderConfig(port="/dev/tty.usbmodem5A460819811", id="my_awesome_leader_arm")
# Initialize the robot and teleoperator
follower = SO100Follower(follower_config)
leader = SO100Leader(leader_config)
def main():
# Create the robot and teleoperator configurations
camera_config = {"front": OpenCVCameraConfig(index_or_path=0, width=640, height=480, fps=FPS)}
follower_config = SO100FollowerConfig(
port="/dev/tty.usbmodem5A460814411",
id="my_awesome_follower_arm",
cameras=camera_config,
use_degrees=True,
)
leader_config = SO100LeaderConfig(port="/dev/tty.usbmodem5A460819811", id="my_awesome_leader_arm")
# NOTE: It is highly recommended to use the urdf in the SO-ARM100 repo: https://github.com/TheRobotStudio/SO-ARM100/blob/main/Simulation/SO101/so101_new_calib.urdf
follower_kinematics_solver = RobotKinematics(
# Initialize the robot and teleoperator
follower = SO100Follower(follower_config)
leader = SO100Leader(leader_config)
# NOTE: It is highly recommended to use the urdf in the SO-ARM100 repo: https://github.com/TheRobotStudio/SO-ARM100/blob/main/Simulation/SO101/so101_new_calib.urdf
follower_kinematics_solver = RobotKinematics(
urdf_path="./SO101/so101_new_calib.urdf",
target_frame_name="gripper_frame_link",
joint_names=list(follower.bus.motors.keys()),
)
)
# NOTE: It is highly recommended to use the urdf in the SO-ARM100 repo: https://github.com/TheRobotStudio/SO-ARM100/blob/main/Simulation/SO101/so101_new_calib.urdf
leader_kinematics_solver = RobotKinematics(
# NOTE: It is highly recommended to use the urdf in the SO-ARM100 repo: https://github.com/TheRobotStudio/SO-ARM100/blob/main/Simulation/SO101/so101_new_calib.urdf
leader_kinematics_solver = RobotKinematics(
urdf_path="./SO101/so101_new_calib.urdf",
target_frame_name="gripper_frame_link",
joint_names=list(leader.bus.motors.keys()),
)
)
# Build pipeline to convert follower joints to EE observation
follower_joints_to_ee = RobotProcessorPipeline[RobotObservation, RobotObservation](
# Build pipeline to convert follower joints to EE observation
follower_joints_to_ee = RobotProcessorPipeline[RobotObservation, RobotObservation](
steps=[
ForwardKinematicsJointsToEE(
kinematics=follower_kinematics_solver, motor_names=list(follower.bus.motors.keys())
@@ -82,10 +87,10 @@ follower_joints_to_ee = RobotProcessorPipeline[RobotObservation, RobotObservatio
],
to_transition=observation_to_transition,
to_output=transition_to_observation,
)
)
# Build pipeline to convert leader joints to EE action
leader_joints_to_ee = RobotProcessorPipeline[tuple[RobotAction, RobotObservation], RobotAction](
# Build pipeline to convert leader joints to EE action
leader_joints_to_ee = RobotProcessorPipeline[tuple[RobotAction, RobotObservation], RobotAction](
steps=[
ForwardKinematicsJointsToEE(
kinematics=leader_kinematics_solver, motor_names=list(leader.bus.motors.keys())
@@ -93,10 +98,10 @@ leader_joints_to_ee = RobotProcessorPipeline[tuple[RobotAction, RobotObservation
],
to_transition=robot_action_observation_to_transition,
to_output=transition_to_robot_action,
)
)
# Build pipeline to convert EE action to follower joints
ee_to_follower_joints = RobotProcessorPipeline[tuple[RobotAction, RobotObservation], RobotAction](
# Build pipeline to convert EE action to follower joints
ee_to_follower_joints = RobotProcessorPipeline[tuple[RobotAction, RobotObservation], RobotAction](
[
EEBoundsAndSafety(
end_effector_bounds={"min": [-1.0, -1.0, -1.0], "max": [1.0, 1.0, 1.0]},
@@ -110,10 +115,10 @@ ee_to_follower_joints = RobotProcessorPipeline[tuple[RobotAction, RobotObservati
],
to_transition=robot_action_observation_to_transition,
to_output=transition_to_robot_action,
)
)
# Create the dataset
dataset = LeRobotDataset.create(
# Create the dataset
dataset = LeRobotDataset.create(
repo_id=HF_REPO_ID,
fps=FPS,
features=combine_feature_dicts(
@@ -133,23 +138,22 @@ dataset = LeRobotDataset.create(
robot_type=follower.name,
use_videos=True,
image_writer_threads=4,
)
)
# Connect the robot and teleoperator
leader.connect()
follower.connect()
# Connect the robot and teleoperator
leader.connect()
follower.connect()
# Initialize the keyboard listener and rerun visualization
listener, events = init_keyboard_listener()
init_rerun(session_name="recording_phone")
# Initialize the keyboard listener and rerun visualization
listener, events = init_keyboard_listener()
init_rerun(session_name="recording_phone")
if not leader.is_connected or not follower.is_connected:
if not leader.is_connected or not follower.is_connected:
raise ValueError("Robot or teleop is not connected!")
print("Starting record loop...")
episode_idx = 0
while episode_idx < NUM_EPISODES and not events["stop_recording"]:
print("Starting record loop...")
episode_idx = 0
while episode_idx < NUM_EPISODES and not events["stop_recording"]:
log_say(f"Recording episode {episode_idx + 1} of {NUM_EPISODES}")
# Main record loop
@@ -194,11 +198,15 @@ while episode_idx < NUM_EPISODES and not events["stop_recording"]:
dataset.save_episode()
episode_idx += 1
# Clean up
log_say("Stop recording")
leader.disconnect()
follower.disconnect()
listener.stop()
# Clean up
log_say("Stop recording")
leader.disconnect()
follower.disconnect()
listener.stop()
dataset.finalize()
dataset.push_to_hub()
dataset.finalize()
dataset.push_to_hub()
if __name__ == "__main__":
main()

58
examples/so100_to_so100_EE/replay.py
View File

@@ -30,29 +30,31 @@ from lerobot.robots.so100_follower.robot_kinematic_processor import (
)
from lerobot.robots.so100_follower.so100_follower import SO100Follower
from lerobot.utils.constants import ACTION
from lerobot.utils.robot_utils import busy_wait
from lerobot.utils.robot_utils import precise_sleep
from lerobot.utils.utils import log_say
EPISODE_IDX = 0
HF_REPO_ID = "<hf_username>/<dataset_repo_id>"
# Initialize the robot config
robot_config = SO100FollowerConfig(
def main():
# Initialize the robot config
robot_config = SO100FollowerConfig(
port="/dev/tty.usbmodem5A460814411", id="my_awesome_follower_arm", use_degrees=True
)
)
# Initialize the robot
robot = SO100Follower(robot_config)
# Initialize the robot
robot = SO100Follower(robot_config)
# NOTE: It is highly recommended to use the urdf in the SO-ARM100 repo: https://github.com/TheRobotStudio/SO-ARM100/blob/main/Simulation/SO101/so101_new_calib.urdf
kinematics_solver = RobotKinematics(
# NOTE: It is highly recommended to use the urdf in the SO-ARM100 repo: https://github.com/TheRobotStudio/SO-ARM100/blob/main/Simulation/SO101/so101_new_calib.urdf
kinematics_solver = RobotKinematics(
urdf_path="./SO101/so101_new_calib.urdf",
target_frame_name="gripper_frame_link",
joint_names=list(robot.bus.motors.keys()),
)
)
# Build pipeline to convert EE action to joints action
robot_ee_to_joints_processor = RobotProcessorPipeline[tuple[RobotAction, RobotObservation], RobotAction](
# Build pipeline to convert EE action to joints action
robot_ee_to_joints_processor = RobotProcessorPipeline[tuple[RobotAction, RobotObservation], RobotAction](
steps=[
InverseKinematicsEEToJoints(
kinematics=kinematics_solver,
@@ -62,23 +64,23 @@ robot_ee_to_joints_processor = RobotProcessorPipeline[tuple[RobotAction, RobotOb
],
to_transition=robot_action_observation_to_transition,
to_output=transition_to_robot_action,
)
)
# Fetch the dataset to replay
dataset = LeRobotDataset(HF_REPO_ID, episodes=[EPISODE_IDX])
# Filter dataset to only include frames from the specified episode since episodes are chunked in dataset V3.0
episode_frames = dataset.hf_dataset.filter(lambda x: x["episode_index"] == EPISODE_IDX)
actions = episode_frames.select_columns(ACTION)
# Fetch the dataset to replay
dataset = LeRobotDataset(HF_REPO_ID, episodes=[EPISODE_IDX])
# Filter dataset to only include frames from the specified episode since episodes are chunked in dataset V3.0
episode_frames = dataset.hf_dataset.filter(lambda x: x["episode_index"] == EPISODE_IDX)
actions = episode_frames.select_columns(ACTION)
# Connect to the robot
robot.connect()
# Connect to the robot
robot.connect()
if not robot.is_connected:
if not robot.is_connected:
raise ValueError("Robot is not connected!")
print("Starting replay loop...")
log_say(f"Replaying episode {EPISODE_IDX}")
for idx in range(len(episode_frames)):
print("Starting replay loop...")
log_say(f"Replaying episode {EPISODE_IDX}")
for idx in range(len(episode_frames)):
t0 = time.perf_counter()
# Get recorded action from dataset
@@ -95,7 +97,11 @@ for idx in range(len(episode_frames)):
# Send action to robot
_ = robot.send_action(joint_action)
busy_wait(1.0 / dataset.fps - (time.perf_counter() - t0))
precise_sleep(1.0 / dataset.fps - (time.perf_counter() - t0))
# Clean up
robot.disconnect()
# Clean up
robot.disconnect()
if __name__ == "__main__":
main()

62
examples/so100_to_so100_EE/teleoperate.py
View File

@@ -32,37 +32,39 @@ from lerobot.robots.so100_follower.robot_kinematic_processor import (
from lerobot.robots.so100_follower.so100_follower import SO100Follower
from lerobot.teleoperators.so100_leader.config_so100_leader import SO100LeaderConfig
from lerobot.teleoperators.so100_leader.so100_leader import SO100Leader
from lerobot.utils.robot_utils import busy_wait
from lerobot.utils.robot_utils import precise_sleep
from lerobot.utils.visualization_utils import init_rerun, log_rerun_data
FPS = 30
# Initialize the robot and teleoperator config
follower_config = SO100FollowerConfig(
def main():
# Initialize the robot and teleoperator config
follower_config = SO100FollowerConfig(
port="/dev/tty.usbmodem5A460814411", id="my_awesome_follower_arm", use_degrees=True
)
leader_config = SO100LeaderConfig(port="/dev/tty.usbmodem5A460819811", id="my_awesome_leader_arm")
)
leader_config = SO100LeaderConfig(port="/dev/tty.usbmodem5A460819811", id="my_awesome_leader_arm")
# Initialize the robot and teleoperator
follower = SO100Follower(follower_config)
leader = SO100Leader(leader_config)
# Initialize the robot and teleoperator
follower = SO100Follower(follower_config)
leader = SO100Leader(leader_config)
# NOTE: It is highly recommended to use the urdf in the SO-ARM100 repo: https://github.com/TheRobotStudio/SO-ARM100/blob/main/Simulation/SO101/so101_new_calib.urdf
follower_kinematics_solver = RobotKinematics(
# NOTE: It is highly recommended to use the urdf in the SO-ARM100 repo: https://github.com/TheRobotStudio/SO-ARM100/blob/main/Simulation/SO101/so101_new_calib.urdf
follower_kinematics_solver = RobotKinematics(
urdf_path="./SO101/so101_new_calib.urdf",
target_frame_name="gripper_frame_link",
joint_names=list(follower.bus.motors.keys()),
)
)
# NOTE: It is highly recommended to use the urdf in the SO-ARM100 repo: https://github.com/TheRobotStudio/SO-ARM100/blob/main/Simulation/SO101/so101_new_calib.urdf
leader_kinematics_solver = RobotKinematics(
# NOTE: It is highly recommended to use the urdf in the SO-ARM100 repo: https://github.com/TheRobotStudio/SO-ARM100/blob/main/Simulation/SO101/so101_new_calib.urdf
leader_kinematics_solver = RobotKinematics(
urdf_path="./SO101/so101_new_calib.urdf",
target_frame_name="gripper_frame_link",
joint_names=list(leader.bus.motors.keys()),
)
)
# Build pipeline to convert teleop joints to EE action
leader_to_ee = RobotProcessorPipeline[RobotAction, RobotAction](
# Build pipeline to convert teleop joints to EE action
leader_to_ee = RobotProcessorPipeline[RobotAction, RobotAction](
steps=[
ForwardKinematicsJointsToEE(
kinematics=leader_kinematics_solver, motor_names=list(leader.bus.motors.keys())
@@ -70,10 +72,10 @@ leader_to_ee = RobotProcessorPipeline[RobotAction, RobotAction](
],
to_transition=robot_action_to_transition,
to_output=transition_to_robot_action,
)
)
# build pipeline to convert EE action to robot joints
ee_to_follower_joints = RobotProcessorPipeline[tuple[RobotAction, RobotObservation], RobotAction](
# build pipeline to convert EE action to robot joints
ee_to_follower_joints = RobotProcessorPipeline[tuple[RobotAction, RobotObservation], RobotAction](
[
EEBoundsAndSafety(
end_effector_bounds={"min": [-1.0, -1.0, -1.0], "max": [1.0, 1.0, 1.0]},
@@ -87,17 +89,17 @@ ee_to_follower_joints = RobotProcessorPipeline[tuple[RobotAction, RobotObservati
],
to_transition=robot_action_observation_to_transition,
to_output=transition_to_robot_action,
)
)
# Connect to the robot and teleoperator
follower.connect()
leader.connect()
# Connect to the robot and teleoperator
follower.connect()
leader.connect()
# Init rerun viewer
init_rerun(session_name="so100_so100_EE_teleop")
# Init rerun viewer
init_rerun(session_name="so100_so100_EE_teleop")
print("Starting teleop loop...")
while True:
print("Starting teleop loop...")
while True:
t0 = time.perf_counter()
# Get robot observation
@@ -118,4 +120,8 @@ while True:
# Visualize
log_rerun_data(observation=leader_ee_act, action=follower_joints_act)
busy_wait(max(1.0 / FPS - (time.perf_counter() - t0), 0.0))
precise_sleep(max(1.0 / FPS - (time.perf_counter() - t0), 0.0))
if __name__ == "__main__":
main()

94
examples/tutorial/act/act_training_example.py
View File

@@ -19,60 +19,62 @@ def make_delta_timestamps(delta_indices: list[int] | None, fps: int) -> list[flo
return [i / fps for i in delta_indices]
output_directory = Path("outputs/robot_learning_tutorial/act")
output_directory.mkdir(parents=True, exist_ok=True)
def main():
output_directory = Path("outputs/robot_learning_tutorial/act")
output_directory.mkdir(parents=True, exist_ok=True)
# Select your device
device = torch.device("mps") # or "cuda" or "cpu"
# Select your device
device = torch.device("mps") # or "cuda" or "cpu"
dataset_id = "lerobot/svla_so101_pickplace"
dataset_id = "lerobot/svla_so101_pickplace"
# This specifies the inputs the model will be expecting and the outputs it will produce
dataset_metadata = LeRobotDatasetMetadata(dataset_id)
features = dataset_to_policy_features(dataset_metadata.features)
# This specifies the inputs the model will be expecting and the outputs it will produce
dataset_metadata = LeRobotDatasetMetadata(dataset_id)
features = dataset_to_policy_features(dataset_metadata.features)
output_features = {key: ft for key, ft in features.items() if ft.type is FeatureType.ACTION}
input_features = {key: ft for key, ft in features.items() if key not in output_features}
output_features = {key: ft for key, ft in features.items() if ft.type is FeatureType.ACTION}
input_features = {key: ft for key, ft in features.items() if key not in output_features}
cfg = ACTConfig(input_features=input_features, output_features=output_features)
policy = ACTPolicy(cfg)
preprocessor, postprocessor = make_pre_post_processors(cfg, dataset_stats=dataset_metadata.stats)
cfg = ACTConfig(input_features=input_features, output_features=output_features)
policy = ACTPolicy(cfg)
preprocessor, postprocessor = make_pre_post_processors(cfg, dataset_stats=dataset_metadata.stats)
policy.train()
policy.to(device)
policy.train()
policy.to(device)
# To perform action chunking, ACT expects a given number of actions as targets
delta_timestamps = {
# To perform action chunking, ACT expects a given number of actions as targets
delta_timestamps = {
"action": make_delta_timestamps(cfg.action_delta_indices, dataset_metadata.fps),
}
}
# add image features if they are present
delta_timestamps |= {
k: make_delta_timestamps(cfg.observation_delta_indices, dataset_metadata.fps) for k in cfg.image_features
}
# add image features if they are present
delta_timestamps |= {
k: make_delta_timestamps(cfg.observation_delta_indices, dataset_metadata.fps)
for k in cfg.image_features
}
# Instantiate the dataset
dataset = LeRobotDataset(dataset_id, delta_timestamps=delta_timestamps)
# Instantiate the dataset
dataset = LeRobotDataset(dataset_id, delta_timestamps=delta_timestamps)
# Create the optimizer and dataloader for offline training
optimizer = cfg.get_optimizer_preset().build(policy.parameters())
batch_size = 32
dataloader = torch.utils.data.DataLoader(
# Create the optimizer and dataloader for offline training
optimizer = cfg.get_optimizer_preset().build(policy.parameters())
batch_size = 32
dataloader = torch.utils.data.DataLoader(
dataset,
batch_size=batch_size,
shuffle=True,
pin_memory=device.type != "cpu",
drop_last=True,
)
)
# Number of training steps and logging frequency
training_steps = 1
log_freq = 1
# Number of training steps and logging frequency
training_steps = 1
log_freq = 1
# Run training loop
step = 0
done = False
while not done:
# Run training loop
step = 0
done = False
while not done:
for batch in dataloader:
batch = preprocessor(batch)
loss, _ = policy.forward(batch)
@@ -87,12 +89,16 @@ while not done:
done = True
break
# Save the policy checkpoint, alongside the pre/post processors
policy.save_pretrained(output_directory)
preprocessor.save_pretrained(output_directory)
postprocessor.save_pretrained(output_directory)
# Save the policy checkpoint, alongside the pre/post processors
policy.save_pretrained(output_directory)
preprocessor.save_pretrained(output_directory)
postprocessor.save_pretrained(output_directory)
# Save all assets to the Hub
policy.push_to_hub("fracapuano/robot_learning_tutorial_act")
preprocessor.push_to_hub("fracapuano/robot_learning_tutorial_act")
postprocessor.push_to_hub("fracapuano/robot_learning_tutorial_act")
# Save all assets to the Hub
policy.push_to_hub("<user>/robot_learning_tutorial_act")
preprocessor.push_to_hub("<user>/robot_learning_tutorial_act")
postprocessor.push_to_hub("<user>/robot_learning_tutorial_act")
if __name__ == "__main__":
main()

54
examples/tutorial/act/act_using_example.py
View File

@@ -8,37 +8,39 @@ from lerobot.policies.utils import build_inference_frame, make_robot_action
from lerobot.robots.so100_follower.config_so100_follower import SO100FollowerConfig
from lerobot.robots.so100_follower.so100_follower import SO100Follower
device = torch.device("mps") # or "cuda" or "cpu"
model_id = "fracapuano/robot_learning_tutorial_act"
model = ACTPolicy.from_pretrained(model_id)
dataset_id = "lerobot/svla_so101_pickplace"
# This only downloads the metadata for the dataset, ~10s of MB even for large-scale datasets
dataset_metadata = LeRobotDatasetMetadata(dataset_id)
preprocess, postprocess = make_pre_post_processors(model.config, dataset_stats=dataset_metadata.stats)
# # find ports using lerobot-find-port
follower_port = ... # something like "/dev/tty.usbmodem58760431631"
# # the robot ids are used the load the right calibration files
follower_id = ... # something like "follower_so100"
MAX_EPISODES = 5
MAX_STEPS_PER_EPISODE = 20
# Robot and environment configuration
# Camera keys must match the name and resolutions of the ones used for training!
# You can check the camera keys expected by a model in the info.json card on the model card on the Hub
camera_config = {
def main():
device = torch.device("mps") # or "cuda" or "cpu"
model_id = "<user>/robot_learning_tutorial_act"
model = ACTPolicy.from_pretrained(model_id)
dataset_id = "lerobot/svla_so101_pickplace"
# This only downloads the metadata for the dataset, ~10s of MB even for large-scale datasets
dataset_metadata = LeRobotDatasetMetadata(dataset_id)
preprocess, postprocess = make_pre_post_processors(model.config, dataset_stats=dataset_metadata.stats)
# # find ports using lerobot-find-port
follower_port = ... # something like "/dev/tty.usbmodem58760431631"
# # the robot ids are used the load the right calibration files
follower_id = ... # something like "follower_so100"
# Robot and environment configuration
# Camera keys must match the name and resolutions of the ones used for training!
# You can check the camera keys expected by a model in the info.json card on the model card on the Hub
camera_config = {
"side": OpenCVCameraConfig(index_or_path=0, width=640, height=480, fps=30),
"up": OpenCVCameraConfig(index_or_path=1, width=640, height=480, fps=30),
}
}
robot_cfg = SO100FollowerConfig(port=follower_port, id=follower_id, cameras=camera_config)
robot = SO100Follower(robot_cfg)
robot.connect()
robot_cfg = SO100FollowerConfig(port=follower_port, id=follower_id, cameras=camera_config)
robot = SO100Follower(robot_cfg)
robot.connect()
for _ in range(MAX_EPISODES):
for _ in range(MAX_EPISODES):
for _ in range(MAX_STEPS_PER_EPISODE):
obs = robot.get_observation()
obs_frame = build_inference_frame(
@@ -55,3 +57,7 @@ for _ in range(MAX_EPISODES):
robot.send_action(action)
print("Episode finished! Starting new episode...")
if __name__ == "__main__":
main()

16
examples/tutorial/async-inf/policy_server.py
View File

@@ -1,11 +1,17 @@
from lerobot.async_inference.configs import PolicyServerConfig
from lerobot.async_inference.policy_server import serve
host = ... # something like "127.0.0.1" if you're exposing to localhost
port = ... # something like 8080
config = PolicyServerConfig(
def main():
host = ... # something like "127.0.0.1" if you're exposing to localhost
port = ... # something like 8080
config = PolicyServerConfig(
host=host,
port=port,
)
serve(config)
)
serve(config)
if __name__ == "__main__":
main()

44
examples/tutorial/async-inf/robot_client.py
View File

@@ -6,41 +6,43 @@ from lerobot.async_inference.robot_client import RobotClient
from lerobot.cameras.opencv.configuration_opencv import OpenCVCameraConfig
from lerobot.robots.so100_follower import SO100FollowerConfig
# these cameras must match the ones expected by the policy - find your cameras with lerobot-find-cameras
# check the config.json on the Hub for the policy you are using to see the expected camera specs
camera_cfg = {
def main():
# these cameras must match the ones expected by the policy - find your cameras with lerobot-find-cameras
# check the config.json on the Hub for the policy you are using to see the expected camera specs
camera_cfg = {
"up": OpenCVCameraConfig(index_or_path=0, width=640, height=480, fps=30),
"side": OpenCVCameraConfig(index_or_path=1, width=640, height=480, fps=30),
}
}
# # find ports using lerobot-find-port
follower_port = ... # something like "/dev/tty.usbmodem58760431631"
# # find ports using lerobot-find-port
follower_port = ... # something like "/dev/tty.usbmodem58760431631"
# # the robot ids are used the load the right calibration files
follower_id = ... # something like "follower_so100"
# # the robot ids are used the load the right calibration files
follower_id = ... # something like "follower_so100"
robot_cfg = SO100FollowerConfig(port=follower_port, id=follower_id, cameras=camera_cfg)
robot_cfg = SO100FollowerConfig(port=follower_port, id=follower_id, cameras=camera_cfg)
server_address = ... # something like "127.0.0.1:8080" if using localhost
server_address = ... # something like "127.0.0.1:8080" if using localhost
# 3. Create client configuration
client_cfg = RobotClientConfig(
# 3. Create client configuration
client_cfg = RobotClientConfig(
robot=robot_cfg,
server_address=server_address,
policy_device="mps",
policy_type="act",
pretrained_name_or_path="fracapuano/robot_learning_tutorial_act",
pretrained_name_or_path="<user>/robot_learning_tutorial_act",
chunk_size_threshold=0.5, # g
actions_per_chunk=50, # make sure this is less than the max actions of the policy
)
)
# 4. Create and start client
client = RobotClient(client_cfg)
# 4. Create and start client
client = RobotClient(client_cfg)
# 5. Provide a textual description of the task
task = ...
# 5. Provide a textual description of the task
task = ...
if client.start():
if client.start():
# Start action receiver thread
action_receiver_thread = threading.Thread(target=client.receive_actions, daemon=True)
action_receiver_thread.start()
@@ -53,3 +55,7 @@ if client.start():
action_receiver_thread.join()
# (Optionally) plot the action queue size
visualize_action_queue_size(client.action_queue_size)
if __name__ == "__main__":
main()

94
examples/tutorial/diffusion/diffusion_training_example.py
View File

@@ -19,61 +19,63 @@ def make_delta_timestamps(delta_indices: list[int] | None, fps: int) -> list[flo
return [i / fps for i in delta_indices]
output_directory = Path("outputs/robot_learning_tutorial/diffusion")
output_directory.mkdir(parents=True, exist_ok=True)
def main():
output_directory = Path("outputs/robot_learning_tutorial/diffusion")
output_directory.mkdir(parents=True, exist_ok=True)
# Select your device
device = torch.device("mps") # or "cuda" or "cpu"
# Select your device
device = torch.device("mps") # or "cuda" or "cpu"
dataset_id = "lerobot/svla_so101_pickplace"
dataset_id = "lerobot/svla_so101_pickplace"
# This specifies the inputs the model will be expecting and the outputs it will produce
dataset_metadata = LeRobotDatasetMetadata(dataset_id)
features = dataset_to_policy_features(dataset_metadata.features)
# This specifies the inputs the model will be expecting and the outputs it will produce
dataset_metadata = LeRobotDatasetMetadata(dataset_id)
features = dataset_to_policy_features(dataset_metadata.features)
output_features = {key: ft for key, ft in features.items() if ft.type is FeatureType.ACTION}
input_features = {key: ft for key, ft in features.items() if key not in output_features}
output_features = {key: ft for key, ft in features.items() if ft.type is FeatureType.ACTION}
input_features = {key: ft for key, ft in features.items() if key not in output_features}
cfg = DiffusionConfig(input_features=input_features, output_features=output_features)
policy = DiffusionPolicy(cfg)
preprocessor, postprocessor = make_pre_post_processors(cfg, dataset_stats=dataset_metadata.stats)
cfg = DiffusionConfig(input_features=input_features, output_features=output_features)
policy = DiffusionPolicy(cfg)
preprocessor, postprocessor = make_pre_post_processors(cfg, dataset_stats=dataset_metadata.stats)
policy.train()
policy.to(device)
policy.train()
policy.to(device)
# To perform action chunking, ACT expects a given number of actions as targets
delta_timestamps = {
# To perform action chunking, ACT expects a given number of actions as targets
delta_timestamps = {
"observation.state": make_delta_timestamps(cfg.observation_delta_indices, dataset_metadata.fps),
"action": make_delta_timestamps(cfg.action_delta_indices, dataset_metadata.fps),
}
}
# add image features if they are present
delta_timestamps |= {
k: make_delta_timestamps(cfg.observation_delta_indices, dataset_metadata.fps) for k in cfg.image_features
}
# add image features if they are present
delta_timestamps |= {
k: make_delta_timestamps(cfg.observation_delta_indices, dataset_metadata.fps)
for k in cfg.image_features
}
# Instantiate the dataset
dataset = LeRobotDataset(dataset_id, delta_timestamps=delta_timestamps)
# Instantiate the dataset
dataset = LeRobotDataset(dataset_id, delta_timestamps=delta_timestamps)
# Create the optimizer and dataloader for offline training
optimizer = cfg.get_optimizer_preset().build(policy.parameters())
batch_size = 32
dataloader = torch.utils.data.DataLoader(
# Create the optimizer and dataloader for offline training
optimizer = cfg.get_optimizer_preset().build(policy.parameters())
batch_size = 32
dataloader = torch.utils.data.DataLoader(
dataset,
batch_size=batch_size,
shuffle=True,
pin_memory=device.type != "cpu",
drop_last=True,
)
)
# Number of training steps and logging frequency
training_steps = 1
log_freq = 1
# Number of training steps and logging frequency
training_steps = 1
log_freq = 1
# Run training loop
step = 0
done = False
while not done:
# Run training loop
step = 0
done = False
while not done:
for batch in dataloader:
batch = preprocessor(batch)
loss, _ = policy.forward(batch)
@@ -88,12 +90,16 @@ while not done:
done = True
break
# Save the policy checkpoint, alongside the pre/post processors
policy.save_pretrained(output_directory)
preprocessor.save_pretrained(output_directory)
postprocessor.save_pretrained(output_directory)
# Save the policy checkpoint, alongside the pre/post processors
policy.save_pretrained(output_directory)
preprocessor.save_pretrained(output_directory)
postprocessor.save_pretrained(output_directory)
# Save all assets to the Hub
policy.push_to_hub("fracapuano/robot_learning_tutorial_diffusion")
preprocessor.push_to_hub("fracapuano/robot_learning_tutorial_diffusion")
postprocessor.push_to_hub("fracapuano/robot_learning_tutorial_diffusion")
# Save all assets to the Hub
policy.push_to_hub("<user>/robot_learning_tutorial_diffusion")
preprocessor.push_to_hub("<user>/robot_learning_tutorial_diffusion")
postprocessor.push_to_hub("<user>/robot_learning_tutorial_diffusion")
if __name__ == "__main__":
main()

56
examples/tutorial/diffusion/diffusion_using_example.py
View File

@@ -8,42 +8,42 @@ from lerobot.policies.utils import build_inference_frame, make_robot_action
from lerobot.robots.so100_follower.config_so100_follower import SO100FollowerConfig
from lerobot.robots.so100_follower.so100_follower import SO100Follower
device = torch.device("mps") # or "cuda" or "cpu"
model_id = "fracapuano/robot_learning_tutorial_diffusion"
model = DiffusionPolicy.from_pretrained(model_id)
dataset_id = "lerobot/svla_so101_pickplace"
# This only downloads the metadata for the dataset, ~10s of MB even for large-scale datasets
dataset_metadata = LeRobotDatasetMetadata(dataset_id)
preprocess, postprocess = make_pre_post_processors(
model.config, model_id, dataset_stats=dataset_metadata.stats
)
MAX_EPISODES = 5
MAX_STEPS_PER_EPISODE = 20
# # find ports using lerobot-find-port
follower_port = ... # something like "/dev/tty.usbmodem58760431631"
def main():
device = torch.device("mps") # or "cuda" or "cpu"
model_id = "<user>/robot_learning_tutorial_diffusion"
# # the robot ids are used the load the right calibration files
follower_id = ... # something like "follower_so100"
model = DiffusionPolicy.from_pretrained(model_id)
# Robot and environment configuration
# Camera keys must match the name and resolutions of the ones used for training!
# You can check the camera keys expected by a model in the info.json card on the model card on the Hub
camera_config = {
dataset_id = "lerobot/svla_so101_pickplace"
# This only downloads the metadata for the dataset, ~10s of MB even for large-scale datasets
dataset_metadata = LeRobotDatasetMetadata(dataset_id)
preprocess, postprocess = make_pre_post_processors(
model.config, model_id, dataset_stats=dataset_metadata.stats
)
# # find ports using lerobot-find-port
follower_port = ... # something like "/dev/tty.usbmodem58760431631"
# # the robot ids are used the load the right calibration files
follower_id = ... # something like "follower_so100"
# Robot and environment configuration
# Camera keys must match the name and resolutions of the ones used for training!
# You can check the camera keys expected by a model in the info.json card on the model card on the Hub
camera_config = {
"side": OpenCVCameraConfig(index_or_path=0, width=640, height=480, fps=30),
"up": OpenCVCameraConfig(index_or_path=1, width=640, height=480, fps=30),
}
}
robot_cfg = SO100FollowerConfig(port=follower_port, id=follower_id, cameras=camera_config)
robot = SO100Follower(robot_cfg)
robot.connect()
robot_cfg = SO100FollowerConfig(port=follower_port, id=follower_id, cameras=camera_config)
robot = SO100Follower(robot_cfg)
robot.connect()
for _ in range(MAX_EPISODES):
for _ in range(MAX_EPISODES):
for _ in range(MAX_STEPS_PER_EPISODE):
obs = robot.get_observation()
obs_frame = build_inference_frame(
@@ -58,3 +58,7 @@ for _ in range(MAX_EPISODES):
robot.send_action(action)
print("Episode finished! Starting new episode...")
if __name__ == "__main__":
main()

54
examples/tutorial/pi0/using_pi0_example.py
View File

@@ -11,46 +11,48 @@ from lerobot.robots.so100_follower.so100_follower import SO100Follower
MAX_EPISODES = 5
MAX_STEPS_PER_EPISODE = 20
device = torch.device("mps") # or "cuda" or "cpu"
model_id = "lerobot/pi0_base"
model = PI0Policy.from_pretrained(model_id)
def main():
device = torch.device("mps") # or "cuda" or "cpu"
model_id = "lerobot/pi0_base"
preprocess, postprocess = make_pre_post_processors(
model = PI0Policy.from_pretrained(model_id)
preprocess, postprocess = make_pre_post_processors(
model.config,
model_id,
# This overrides allows to run on MPS, otherwise defaults to CUDA (if available)
preprocessor_overrides={"device_processor": {"device": str(device)}},
)
)
# find ports using lerobot-find-port
follower_port = ... # something like "/dev/tty.usbmodem58760431631"
# find ports using lerobot-find-port
follower_port = ... # something like "/dev/tty.usbmodem58760431631"
# the robot ids are used the load the right calibration files
follower_id = ... # something like "follower_so100"
# the robot ids are used the load the right calibration files
follower_id = ... # something like "follower_so100"
# Robot and environment configuration
# Camera keys must match the name and resolutions of the ones used for training!
# You can check the camera keys expected by a model in the info.json card on the model card on the Hub
camera_config = {
# Robot and environment configuration
# Camera keys must match the name and resolutions of the ones used for training!
# You can check the camera keys expected by a model in the info.json card on the model card on the Hub
camera_config = {
"base_0_rgb": OpenCVCameraConfig(index_or_path=0, width=640, height=480, fps=30),
"left_wrist_0_rgb": OpenCVCameraConfig(index_or_path=1, width=640, height=480, fps=30),
"right_wrist_0_rgb": OpenCVCameraConfig(index_or_path=2, width=640, height=480, fps=30),
}
}
robot_cfg = SO100FollowerConfig(port=follower_port, id=follower_id, cameras=camera_config)
robot = SO100Follower(robot_cfg)
robot.connect()
robot_cfg = SO100FollowerConfig(port=follower_port, id=follower_id, cameras=camera_config)
robot = SO100Follower(robot_cfg)
robot.connect()
task = "" # something like "pick the red block"
robot_type = "" # something like "so100_follower" for multi-embodiment datasets
task = "" # something like "pick the red block"
robot_type = "" # something like "so100_follower" for multi-embodiment datasets
# This is used to match the raw observation keys to the keys expected by the policy
action_features = hw_to_dataset_features(robot.action_features, "action")
obs_features = hw_to_dataset_features(robot.observation_features, "observation")
dataset_features = {**action_features, **obs_features}
# This is used to match the raw observation keys to the keys expected by the policy
action_features = hw_to_dataset_features(robot.action_features, "action")
obs_features = hw_to_dataset_features(robot.observation_features, "observation")
dataset_features = {**action_features, **obs_features}
for _ in range(MAX_EPISODES):
for _ in range(MAX_EPISODES):
for _ in range(MAX_STEPS_PER_EPISODE):
obs = robot.get_observation()
obs_frame = build_inference_frame(
@@ -65,3 +67,7 @@ for _ in range(MAX_EPISODES):
robot.send_action(action)
print("Episode finished! Starting new episode...")
if __name__ == "__main__":
main()

120
examples/tutorial/rl/hilserl_example.py
View File

@@ -20,6 +20,8 @@ from lerobot.teleoperators.utils import TeleopEvents
LOG_EVERY = 10
SEND_EVERY = 10
MAX_EPISODES = 5
MAX_STEPS_PER_EPISODE = 20
def run_learner(
@@ -223,80 +225,76 @@ def make_policy_obs(obs, device: torch.device = "cpu"):
}
"""Main function - coordinates actor and learner processes."""
def main():
"""Main function - coordinates actor and learner processes."""
device = "mps" # or "cuda" or "cpu"
output_directory = Path("outputs/robot_learning_tutorial/hil_serl")
output_directory.mkdir(parents=True, exist_ok=True)
device = "mps" # or "cuda" or "cpu"
output_directory = Path("outputs/robot_learning_tutorial/hil_serl")
output_directory.mkdir(parents=True, exist_ok=True)
# find ports using lerobot-find-port
follower_port = ...
leader_port = ...
# find ports using lerobot-find-port
follower_port = ...
leader_port = ...
# the robot ids are used the load the right calibration files
follower_id = ...
leader_id = ...
# the robot ids are used the load the right calibration files
follower_id = ...
leader_id = ...
# A pretrained model (to be used in-distribution!)
reward_classifier_id = "fracapuano/reward_classifier_hil_serl_example"
reward_classifier = Classifier.from_pretrained(reward_classifier_id)
# A pretrained model (to be used in-distribution!)
reward_classifier_id = "<user>/reward_classifier_hil_serl_example"
reward_classifier = Classifier.from_pretrained(reward_classifier_id)
reward_classifier.to(device)
reward_classifier.eval()
reward_classifier.to(device)
reward_classifier.eval()
MAX_EPISODES = 5
MAX_STEPS_PER_EPISODE = 20
# Robot and environment configuration
robot_cfg = SO100FollowerConfig(port=follower_port, id=follower_id)
teleop_cfg = SO100LeaderConfig(port=leader_port, id=leader_id)
processor_cfg = HILSerlProcessorConfig(control_mode="leader")
# Robot and environment configuration
robot_cfg = SO100FollowerConfig(port=follower_port, id=follower_id)
teleop_cfg = SO100LeaderConfig(port=leader_port, id=leader_id)
processor_cfg = HILSerlProcessorConfig(control_mode="leader")
env_cfg = HILSerlRobotEnvConfig(robot=robot_cfg, teleop=teleop_cfg, processor=processor_cfg)
env_cfg = HILSerlRobotEnvConfig(robot=robot_cfg, teleop=teleop_cfg, processor=processor_cfg)
# Create robot environment
env, teleop_device = make_robot_env(env_cfg)
# Create robot environment
env, teleop_device = make_robot_env(env_cfg)
obs_features = hw_to_dataset_features(env.robot.observation_features, "observation")
action_features = hw_to_dataset_features(env.robot.action_features, "action")
obs_features = hw_to_dataset_features(env.robot.observation_features, "observation")
action_features = hw_to_dataset_features(env.robot.action_features, "action")
# Create SAC policy for action selection
policy_cfg = SACConfig(
# Create SAC policy for action selection
policy_cfg = SACConfig(
device=device,
input_features=obs_features,
output_features=action_features,
)
)
policy_actor = SACPolicy(policy_cfg)
policy_learner = SACPolicy(policy_cfg)
policy_actor = SACPolicy(policy_cfg)
policy_learner = SACPolicy(policy_cfg)
demonstrations_repo_id = "lerobot/example_hil_serl_dataset"
offline_dataset = LeRobotDataset(repo_id=demonstrations_repo_id)
demonstrations_repo_id = "lerobot/example_hil_serl_dataset"
offline_dataset = LeRobotDataset(repo_id=demonstrations_repo_id)
# Online buffer: initialized from scratch
online_replay_buffer = ReplayBuffer(device=device, state_keys=list(obs_features.keys()))
# Offline buffer: Created from dataset (pre-populated it with demonstrations)
offline_replay_buffer = ReplayBuffer.from_lerobot_dataset(
# Online buffer: initialized from scratch
online_replay_buffer = ReplayBuffer(device=device, state_keys=list(obs_features.keys()))
# Offline buffer: Created from dataset (pre-populated it with demonstrations)
offline_replay_buffer = ReplayBuffer.from_lerobot_dataset(
lerobot_dataset=offline_dataset, device=device, state_keys=list(obs_features.keys())
)
)
# Create communication channels between learner and actor processes
transitions_queue = mp.Queue(maxsize=10)
parameters_queue = mp.Queue(maxsize=2)
shutdown_event = mp.Event()
# Create communication channels between learner and actor processes
transitions_queue = mp.Queue(maxsize=10)
parameters_queue = mp.Queue(maxsize=2)
shutdown_event = mp.Event()
# Signal handler for graceful shutdown
def signal_handler(sig):
# Signal handler for graceful shutdown
def signal_handler(sig):
print(f"\nSignal {sig} received, shutting down...")
shutdown_event.set()
signal.signal(signal.SIGINT, signal_handler)
signal.signal(signal.SIGTERM, signal_handler)
signal.signal(signal.SIGINT, signal_handler)
signal.signal(signal.SIGTERM, signal_handler)
# Create processes
learner_process = mp.Process(
# Create processes
learner_process = mp.Process(
target=run_learner,
args=(
transitions_queue,
@@ -307,9 +305,9 @@ learner_process = mp.Process(
offline_replay_buffer,
),
kwargs={"device": device}, # can run on accelerated hardware for training
)
)
actor_process = mp.Process(
actor_process = mp.Process(
target=run_actor,
args=(
transitions_queue,
@@ -321,25 +319,29 @@ actor_process = mp.Process(
output_directory,
),
kwargs={"device": "cpu"}, # actor is frozen, can run on CPU or accelerate for inference
)
)
learner_process.start()
actor_process.start()
learner_process.start()
actor_process.start()
try:
try:
# Wait for actor to finish (it controls the episode loop)
actor_process.join()
shutdown_event.set()
learner_process.join(timeout=10)
except KeyboardInterrupt:
except KeyboardInterrupt:
print("Main process interrupted")
shutdown_event.set()
actor_process.join(timeout=5)
learner_process.join(timeout=10)
finally:
finally:
if learner_process.is_alive():
learner_process.terminate()
if actor_process.is_alive():
actor_process.terminate()
if __name__ == "__main__":
main()

51
examples/tutorial/rl/reward_classifier_example.py
View File

@@ -4,37 +4,38 @@ from lerobot.datasets.lerobot_dataset import LeRobotDataset
from lerobot.policies.factory import make_policy, make_pre_post_processors
from lerobot.policies.sac.reward_model.configuration_classifier import RewardClassifierConfig
# Device to use for training
device = "mps" # or "cuda", or "cpu"
# Load the dataset used for training
repo_id = "lerobot/example_hil_serl_dataset"
dataset = LeRobotDataset(repo_id)
def main():
# Device to use for training
device = "mps" # or "cuda", or "cpu"
# Configure the policy to extract features from the image frames
camera_keys = dataset.meta.camera_keys
# Load the dataset used for training
repo_id = "lerobot/example_hil_serl_dataset"
dataset = LeRobotDataset(repo_id)
config = RewardClassifierConfig(
# Configure the policy to extract features from the image frames
camera_keys = dataset.meta.camera_keys
config = RewardClassifierConfig(
num_cameras=len(camera_keys),
device=device,
# backbone model to extract features from the image frames
model_name="microsoft/resnet-18",
)
)
# Make policy, preprocessor, and optimizer
policy = make_policy(config, ds_meta=dataset.meta)
optimizer = config.get_optimizer_preset().build(policy.parameters())
preprocessor, _ = make_pre_post_processors(policy_cfg=config, dataset_stats=dataset.meta.stats)
# Make policy, preprocessor, and optimizer
policy = make_policy(config, ds_meta=dataset.meta)
optimizer = config.get_optimizer_preset().build(policy.parameters())
preprocessor, _ = make_pre_post_processors(policy_cfg=config, dataset_stats=dataset.meta.stats)
classifier_id = "<user>/reward_classifier_hil_serl_example"
classifier_id = "fracapuano/reward_classifier_hil_serl_example"
# Instantiate a dataloader
dataloader = torch.utils.data.DataLoader(dataset, batch_size=16, shuffle=True)
# Instantiate a dataloader
dataloader = torch.utils.data.DataLoader(dataset, batch_size=16, shuffle=True)
# Training loop
num_epochs = 5
for epoch in range(num_epochs):
# Training loop
num_epochs = 5
for epoch in range(num_epochs):
total_loss = 0
total_accuracy = 0
for batch in dataloader:
@@ -56,7 +57,11 @@ for epoch in range(num_epochs):
avg_accuracy = total_accuracy / len(dataloader)
print(f"Epoch {epoch + 1}/{num_epochs}, Loss: {avg_loss:.4f}, Accuracy: {avg_accuracy:.2f}%")
print("Training finished!")
print("Training finished!")
# You can now save the trained policy.
policy.push_to_hub(classifier_id)
# You can now save the trained policy.
policy.push_to_hub(classifier_id)
if __name__ == "__main__":
main()

54
examples/tutorial/smolvla/using_smolvla_example.py
View File

@@ -11,45 +11,47 @@ from lerobot.robots.so100_follower.so100_follower import SO100Follower
MAX_EPISODES = 5
MAX_STEPS_PER_EPISODE = 20
device = torch.device("mps") # or "cuda" or "cpu"
model_id = "lerobot/smolvla_base"
model = SmolVLAPolicy.from_pretrained(model_id)
def main():
device = torch.device("mps") # or "cuda" or "cpu"
model_id = "lerobot/smolvla_base"
preprocess, postprocess = make_pre_post_processors(
model = SmolVLAPolicy.from_pretrained(model_id)
preprocess, postprocess = make_pre_post_processors(
model.config,
model_id,
# This overrides allows to run on MPS, otherwise defaults to CUDA (if available)
preprocessor_overrides={"device_processor": {"device": str(device)}},
)
)
# find ports using lerobot-find-port
follower_port = ... # something like "/dev/tty.usbmodem58760431631"
# find ports using lerobot-find-port
follower_port = ... # something like "/dev/tty.usbmodem58760431631"
# the robot ids are used the load the right calibration files
follower_id = ... # something like "follower_so100"
# the robot ids are used the load the right calibration files
follower_id = ... # something like "follower_so100"
# Robot and environment configuration
# Camera keys must match the name and resolutions of the ones used for training!
# You can check the camera keys expected by a model in the info.json card on the model card on the Hub
camera_config = {
# Robot and environment configuration
# Camera keys must match the name and resolutions of the ones used for training!
# You can check the camera keys expected by a model in the info.json card on the model card on the Hub
camera_config = {
"camera1": OpenCVCameraConfig(index_or_path=0, width=640, height=480, fps=30),
"camera2": OpenCVCameraConfig(index_or_path=1, width=640, height=480, fps=30),
}
}
robot_cfg = SO100FollowerConfig(port=follower_port, id=follower_id, cameras=camera_config)
robot = SO100Follower(robot_cfg)
robot.connect()
robot_cfg = SO100FollowerConfig(port=follower_port, id=follower_id, cameras=camera_config)
robot = SO100Follower(robot_cfg)
robot.connect()
task = "" # something like "pick the red block"
robot_type = "" # something like "so100_follower" for multi-embodiment datasets
task = "" # something like "pick the red block"
robot_type = "" # something like "so100_follower" for multi-embodiment datasets
# This is used to match the raw observation keys to the keys expected by the policy
action_features = hw_to_dataset_features(robot.action_features, "action")
obs_features = hw_to_dataset_features(robot.observation_features, "observation")
dataset_features = {**action_features, **obs_features}
# This is used to match the raw observation keys to the keys expected by the policy
action_features = hw_to_dataset_features(robot.action_features, "action")
obs_features = hw_to_dataset_features(robot.observation_features, "observation")
dataset_features = {**action_features, **obs_features}
for _ in range(MAX_EPISODES):
for _ in range(MAX_EPISODES):
for _ in range(MAX_STEPS_PER_EPISODE):
obs = robot.get_observation()
obs_frame = build_inference_frame(
@@ -64,3 +66,7 @@ for _ in range(MAX_EPISODES):
robot.send_action(action)
print("Episode finished! Starting new episode...")
if __name__ == "__main__":
main()

347
examples/unitree_g1/gr00t_locomotion.py Normal file
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@@ -0,0 +1,347 @@
#!/usr/bin/env python
# Copyright 2025 The HuggingFace Inc. team. All rights reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
"""
Example: GR00T Locomotion with Pre-loaded Policies
This example demonstrates the NEW pattern for loading GR00T policies externally
and passing them to the robot class.
"""
import argparse
import logging
import threading
import time
from collections import deque
import numpy as np
import onnxruntime as ort
from huggingface_hub import hf_hub_download
from lerobot.robots.unitree_g1.config_unitree_g1 import UnitreeG1Config
from lerobot.robots.unitree_g1.unitree_g1 import UnitreeG1
logger = logging.getLogger(__name__)
GROOT_DEFAULT_ANGLES = np.zeros(29, dtype=np.float32)
GROOT_DEFAULT_ANGLES[[0, 6]] = -0.1 # hip pitch
GROOT_DEFAULT_ANGLES[[3, 9]] = 0.3 # knee
GROOT_DEFAULT_ANGLES[[4, 10]] = -0.2 # ankle pitch
MISSING_JOINTS = []
G1_MODEL = "g1_23" # or "g1_29"
if G1_MODEL == "g1_23":
MISSING_JOINTS = [12, 14, 20, 21, 27, 28] # waist yaw/pitch, wrist pitch/yaw
LOCOMOTION_ACTION_SCALE = 0.25
LOCOMOTION_CONTROL_DT = 0.02
ANG_VEL_SCALE: float = 0.25
DOF_POS_SCALE: float = 1.0
DOF_VEL_SCALE: float = 0.05
CMD_SCALE: list = [2.0, 2.0, 0.25]
DEFAULT_GROOT_REPO_ID = "nepyope/GR00T-WholeBodyControl_g1"
def load_groot_policies(
repo_id: str = DEFAULT_GROOT_REPO_ID,
) -> tuple[ort.InferenceSession, ort.InferenceSession]:
"""Load GR00T dual-policy system (Balance + Walk) from Hugging Face Hub.
Args:
repo_id: Hugging Face Hub repository ID containing the ONNX policies.
"""
logger.info(f"Loading GR00T dual-policy system from Hugging Face Hub ({repo_id})...")
# Download ONNX policies from Hugging Face Hub
balance_path = hf_hub_download(
repo_id=repo_id,
filename="GR00T-WholeBodyControl-Balance.onnx",
)
walk_path = hf_hub_download(
repo_id=repo_id,
filename="GR00T-WholeBodyControl-Walk.onnx",
)
# Load ONNX policies
policy_balance = ort.InferenceSession(balance_path)
policy_walk = ort.InferenceSession(walk_path)
logger.info("GR00T policies loaded successfully")
return policy_balance, policy_walk
class GrootLocomotionController:
"""
Handles GR00T-style locomotion control for the Unitree G1 robot.
This controller manages:
- Dual-policy system (Balance + Walk)
- 29-joint observation processing
- 15D action output (legs + waist)
- Policy inference and motor command generation
"""
def __init__(self, policy_balance, policy_walk, robot, config):
self.policy_balance = policy_balance
self.policy_walk = policy_walk
self.robot = robot
self.config = config
self.locomotion_cmd = np.array([0.0, 0.0, 0.0], dtype=np.float32) # vx, vy, theta_dot
# GR00T-specific state
self.groot_qj_all = np.zeros(29, dtype=np.float32)
self.groot_dqj_all = np.zeros(29, dtype=np.float32)
self.groot_action = np.zeros(15, dtype=np.float32)
self.groot_obs_single = np.zeros(86, dtype=np.float32)
self.groot_obs_history = deque(maxlen=6)
self.groot_obs_stacked = np.zeros(516, dtype=np.float32)
self.groot_height_cmd = 0.74 # Default base height
self.groot_orientation_cmd = np.array([0.0, 0.0, 0.0], dtype=np.float32)
# input to gr00t is 6 frames (6*86D=516)
for _ in range(6):
self.groot_obs_history.append(np.zeros(86, dtype=np.float32))
# Thread management
self.locomotion_running = False
self.locomotion_thread = None
logger.info("GrootLocomotionController initialized")
def groot_locomotion_run(self):
# get current observation
robot_state = self.robot.get_observation()
if robot_state is None:
return
# get command from remote controller
if robot_state.wireless_remote is not None:
self.robot.remote_controller.set(robot_state.wireless_remote)
if self.robot.remote_controller.button[0]: # R1 - raise waist
self.groot_height_cmd += 0.001
self.groot_height_cmd = np.clip(self.groot_height_cmd, 0.50, 1.00)
if self.robot.remote_controller.button[4]: # R2 - lower waist
self.groot_height_cmd -= 0.001
self.groot_height_cmd = np.clip(self.groot_height_cmd, 0.50, 1.00)
else:
self.robot.remote_controller.lx = 0.0
self.robot.remote_controller.ly = 0.0
self.robot.remote_controller.rx = 0.0
self.robot.remote_controller.ry = 0.0
self.locomotion_cmd[0] = self.robot.remote_controller.ly # forward/backward
self.locomotion_cmd[1] = self.robot.remote_controller.lx * -1 # left/right
self.locomotion_cmd[2] = self.robot.remote_controller.rx * -1 # rotation rate
for i in range(29):
self.groot_qj_all[i] = robot_state.motor_state[i].q
self.groot_dqj_all[i] = robot_state.motor_state[i].dq
# adapt observation for g1_23dof
for idx in MISSING_JOINTS:
self.groot_qj_all[idx] = 0.0
self.groot_dqj_all[idx] = 0.0
# Scale joint positions and velocities
qj_obs = self.groot_qj_all.copy()
dqj_obs = self.groot_dqj_all.copy()
# express imu data in gravity frame of reference
quat = robot_state.imu_state.quaternion
ang_vel = np.array(robot_state.imu_state.gyroscope, dtype=np.float32)
gravity_orientation = self.robot.get_gravity_orientation(quat)
# scale joint positions and velocities before policy inference
qj_obs = (qj_obs - GROOT_DEFAULT_ANGLES) * DOF_POS_SCALE
dqj_obs = dqj_obs * DOF_VEL_SCALE
ang_vel_scaled = ang_vel * ANG_VEL_SCALE
# build single frame observation
self.groot_obs_single[:3] = self.locomotion_cmd * np.array(CMD_SCALE)
self.groot_obs_single[3] = self.groot_height_cmd
self.groot_obs_single[4:7] = self.groot_orientation_cmd
self.groot_obs_single[7:10] = ang_vel_scaled
self.groot_obs_single[10:13] = gravity_orientation
self.groot_obs_single[13:42] = qj_obs
self.groot_obs_single[42:71] = dqj_obs
self.groot_obs_single[71:86] = self.groot_action # 15D previous actions
# Add to history and stack observations (6 frames × 86D = 516D)
self.groot_obs_history.append(self.groot_obs_single.copy())
# Stack all 6 frames into 516D vector
for i, obs_frame in enumerate(self.groot_obs_history):
start_idx = i * 86
end_idx = start_idx + 86
self.groot_obs_stacked[start_idx:end_idx] = obs_frame
# Run policy inference (ONNX) with 516D stacked observation
cmd_magnitude = np.linalg.norm(self.locomotion_cmd)
selected_policy = (
self.policy_balance if cmd_magnitude < 0.05 else self.policy_walk
) # balance/standing policy for small commands, walking policy for movement commands
# run policy inference
ort_inputs = {selected_policy.get_inputs()[0].name: np.expand_dims(self.groot_obs_stacked, axis=0)}
ort_outs = selected_policy.run(None, ort_inputs)
self.groot_action = ort_outs[0].squeeze()
# transform action back to target joint positions
target_dof_pos_15 = GROOT_DEFAULT_ANGLES[:15] + self.groot_action * LOCOMOTION_ACTION_SCALE
# command motors
for i in range(15):
motor_idx = i
self.robot.msg.motor_cmd[motor_idx].q = target_dof_pos_15[i]
self.robot.msg.motor_cmd[motor_idx].qd = 0
self.robot.msg.motor_cmd[motor_idx].kp = self.robot.kp[motor_idx]
self.robot.msg.motor_cmd[motor_idx].kd = self.robot.kd[motor_idx]
self.robot.msg.motor_cmd[motor_idx].tau = 0
# adapt action for g1_23dof
for joint_idx in MISSING_JOINTS:
self.robot.msg.motor_cmd[joint_idx].q = 0.0
self.robot.msg.motor_cmd[joint_idx].qd = 0
self.robot.msg.motor_cmd[joint_idx].kp = self.robot.kp[joint_idx]
self.robot.msg.motor_cmd[joint_idx].kd = self.robot.kd[joint_idx]
self.robot.msg.motor_cmd[joint_idx].tau = 0
# send action to robot
self.robot.send_action(self.robot.msg)
def _locomotion_thread_loop(self):
"""Background thread that runs the locomotion policy at specified rate."""
logger.info("Locomotion thread started")
while self.locomotion_running:
start_time = time.time()
try:
self.groot_locomotion_run()
except Exception as e:
logger.error(f"Error in locomotion loop: {e}")
# Sleep to maintain control rate
elapsed = time.time() - start_time
sleep_time = max(0, LOCOMOTION_CONTROL_DT - elapsed)
time.sleep(sleep_time)
logger.info("Locomotion thread stopped")
def start_locomotion_thread(self):
if self.locomotion_running:
logger.warning("Locomotion thread already running")
return
logger.info("Starting locomotion control thread...")
self.locomotion_running = True
self.locomotion_thread = threading.Thread(target=self._locomotion_thread_loop, daemon=True)
self.locomotion_thread.start()
logger.info("Locomotion control thread started!")
def stop_locomotion_thread(self):
if not self.locomotion_running:
return
logger.info("Stopping locomotion control thread...")
self.locomotion_running = False
if self.locomotion_thread:
self.locomotion_thread.join(timeout=2.0)
logger.info("Locomotion control thread stopped")
def reset_robot(self):
"""Move robot legs to default standing position over 2 seconds (arms are not moved)."""
total_time = 3.0
num_step = int(total_time / self.robot.control_dt)
# Only control legs, not arms (first 12 joints)
default_pos = GROOT_DEFAULT_ANGLES # First 12 values are leg angles
dof_size = len(default_pos)
# Get current lowstate
robot_state = self.robot.get_observation()
# Record the current leg positions
init_dof_pos = np.zeros(dof_size, dtype=np.float32)
for i in range(dof_size):
init_dof_pos[i] = robot_state.motor_state[i].q
# Move legs to default pos
for i in range(num_step):
alpha = i / num_step
for motor_idx in range(dof_size):
target_pos = default_pos[motor_idx]
self.robot.msg.motor_cmd[motor_idx].q = (
init_dof_pos[motor_idx] * (1 - alpha) + target_pos * alpha
)
self.robot.msg.motor_cmd[motor_idx].qd = 0
self.robot.msg.motor_cmd[motor_idx].kp = self.robot.kp[motor_idx]
self.robot.msg.motor_cmd[motor_idx].kd = self.robot.kd[motor_idx]
self.robot.msg.motor_cmd[motor_idx].tau = 0
self.robot.msg.crc = self.robot.crc.Crc(self.robot.msg)
self.robot.lowcmd_publisher.Write(self.robot.msg)
time.sleep(self.robot.control_dt)
logger.info("Reached default position (legs only)")
if __name__ == "__main__":
parser = argparse.ArgumentParser(description="GR00T Locomotion Controller for Unitree G1")
parser.add_argument(
"--repo-id",
type=str,
default=DEFAULT_GROOT_REPO_ID,
help=f"Hugging Face Hub repo ID for GR00T policies (default: {DEFAULT_GROOT_REPO_ID})",
)
args = parser.parse_args()
# load policies
policy_balance, policy_walk = load_groot_policies(repo_id=args.repo_id)
# initialize robot
config = UnitreeG1Config()
robot = UnitreeG1(config)
# initialize gr00t locomotion controller
groot_controller = GrootLocomotionController(
policy_balance=policy_balance,
policy_walk=policy_walk,
robot=robot,
config=config,
)
# reset legs and start locomotion thread
try:
groot_controller.reset_robot()
groot_controller.start_locomotion_thread()
# log status
logger.info("Robot initialized with GR00T locomotion policies")
logger.info("Locomotion controller running in background thread")
logger.info("Press Ctrl+C to stop")
# keep robot alive
while True:
time.sleep(1.0)
except KeyboardInterrupt:
print("\nStopping locomotion...")
groot_controller.stop_locomotion_thread()
print("Done!")

47
examples/voice_control/README.md Normal file
View File

@@ -0,0 +1,47 @@
# Voice Assistant Examples
Voice-enabled robot assistant examples using speech-to-text (STT), and text-to-speech (TTS).
## Overview
These examples demonstrate how to build a voice interface for robot control:
1. **Hold SPACE** → Push-to-talk recording starts
2. **Release SPACE** → Recording stops
3. **STT (Whisper)** → Converts speech to text (high-level task prompt)
4. **Pi0.5** → Generates robot response/utterance
5. **TTS (Kokoro)** → Speaks the response back
## Requirements
```bash
pip install torch transformers sounddevice numpy pynput kokoro>=0.9.2
```
## Usage
### With Pi0.5 Model
```bash
python examples/voice_assistant/voice_assistant_pi05.py \
--pretrained_path path/to/pi05/checkpoint
```
## How It Works
### Pi0.5 Voice Integration
Pi0.5 can generate robot utterances as part of its subtask prediction. The flow:
1. **High-level prompt**: User voice command is transcribed and formatted as a task prompt
2. **Subtask generation**: Pi0.5 autoregressively generates a response
3. **Utterance extraction**: If the response contains `<utterance>...</utterance>` tags, the content is extracted
4. **TTS output**: The response is spoken back to the user
## Configuration Options
| Option | Default | Description |
|--------|---------|-------------|
| `--pretrained_path` | None | Path to Pi0.5 checkpoint |
| `--record_seconds` | 5.0 | Audio recording duration |
| `--max_response_tokens` | 100 | Max tokens in generated response |

336
examples/voice_control/voice_assistant_pi05.py Normal file
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@@ -0,0 +1,336 @@
#!/usr/bin/env python
"""
Voice Assistant with Pi0.5: Microphone → STT → Pi0.5 → TTS → Speaker
This example demonstrates how to use Pi0.5 as a conversational robot assistant:
1. Hold SPACE to record your voice command
2. Speech-to-text (Whisper) converts speech to text
3. Text is fed as a high-level prompt to Pi0.5
4. Pi0.5 generates a response (robot utterance)
5. Text-to-speech (Kokoro) speaks the response back
Requirements:
pip install torch transformers sounddevice numpy pynput kokoro>=0.9.2
Usage:
python examples/voice_assistant/voice_assistant_pi05.py \
--pretrained_path lerobot/pi0.5-base
"""
import os
os.environ["TOKENIZERS_PARALLELISM"] = "false"
import argparse
import re
import subprocess
import threading
import time
import numpy as np
import sounddevice as sd
import torch
from pynput import keyboard
from transformers import AutoTokenizer, WhisperForConditionalGeneration, WhisperProcessor
from lerobot.policies.pi05.configuration_pi05 import PI05Config
from lerobot.policies.pi05.modeling_pi05 import PI05Pytorch
SAMPLE_RATE = 16000
def get_device():
if torch.cuda.is_available():
return torch.device("cuda")
elif torch.backends.mps.is_available():
return torch.device("mps")
return torch.device("cpu")
class Pi05VoiceAssistant:
"""Voice assistant using Pi0.5 for generating robot utterances."""
def __init__(
self,
pretrained_path: str | None = None,
max_response_tokens: int = 100,
max_record_seconds: float = 30.0,
):
self.device = get_device()
self.dtype = torch.float32 if self.device.type == "mps" else torch.bfloat16
self.max_response_tokens = max_response_tokens
self.max_record_seconds = max_record_seconds
# Push-to-talk state
self._recording = False
self._audio_chunks: list[np.ndarray] = []
self._stream: sd.InputStream | None = None
print(f"Using device: {self.device}")
self._load_models(pretrained_path)
def _load_models(self, pretrained_path: str | None):
print("Loading STT (Whisper tiny)...")
self.stt_processor = WhisperProcessor.from_pretrained("openai/whisper-tiny.en")
self.stt_model = WhisperForConditionalGeneration.from_pretrained(
"openai/whisper-tiny.en", torch_dtype=self.dtype
).to(self.device)
print("Loading Pi0.5 model...")
self._load_pi05(pretrained_path)
print("Loading tokenizer...")
self.tokenizer = AutoTokenizer.from_pretrained("google/paligemma-3b-pt-224")
self._load_tts()
print("Ready!\n")
def _load_pi05(self, pretrained_path: str | None):
"""Load Pi0.5 model for utterance generation."""
config = PI05Config()
config.dtype = "float32" if self.device.type == "mps" else "bfloat16"
self.pi05_model = PI05Pytorch(config)
if pretrained_path:
try:
from safetensors.torch import load_file
state_dict = load_file(f"{pretrained_path}/model.safetensors")
self.pi05_model.load_state_dict(state_dict, strict=False)
print(f"✓ Loaded Pi0.5 weights from {pretrained_path}")
except Exception as e:
print(f"Warning: Could not load pretrained weights: {e}")
print("Using randomly initialized model for demo purposes")
self.pi05_model = self.pi05_model.to(self.device)
self.pi05_model.eval()
def _load_tts(self):
try:
print("Loading TTS (Kokoro 82M)...")
from kokoro import KPipeline
self.tts_pipeline = KPipeline(lang_code="a") # American English
self.tts_voice = "af_heart"
self.tts_type = "kokoro"
print("Kokoro loaded!")
except Exception as e:
print(f"Kokoro not available ({e})")
print("Using macOS `say` for TTS")
self.tts_pipeline = None
self.tts_type = "system"
def _audio_callback(self, indata, frames, time_info, status):
"""Callback for audio stream - collects chunks while recording."""
if self._recording:
self._audio_chunks.append(indata.copy())
def _start_recording(self):
"""Start recording audio."""
if self._recording:
return
self._recording = True
self._audio_chunks = []
print("🎤 Recording... (release SPACE to stop)")
def _stop_recording(self) -> np.ndarray | None:
"""Stop recording and return the audio."""
if not self._recording:
return None
self._recording = False
if not self._audio_chunks:
return None
audio = np.concatenate(self._audio_chunks, axis=0).flatten()
duration = len(audio) / SAMPLE_RATE
volume = np.abs(audio).max()
print(f"Recorded {duration:.1f}s, volume: {volume:.4f}")
if volume < 0.001:
print("⚠️ Very low audio - check microphone permissions!")
return None
return audio
def wait_for_spacebar(self) -> np.ndarray | None:
"""Wait for spacebar press, record while held, return audio on release."""
audio_result = None
recording_done = threading.Event()
def on_press(key):
if key == keyboard.Key.space:
self._start_recording()
def on_release(key):
nonlocal audio_result
if key == keyboard.Key.space and self._recording:
audio_result = self._stop_recording()
recording_done.set()
return False # Stop listener
# Start audio stream
self._stream = sd.InputStream(
samplerate=SAMPLE_RATE,
channels=1,
dtype="float32",
callback=self._audio_callback,
blocksize=int(SAMPLE_RATE * 0.1), # 100ms blocks
)
with self._stream:
print("\n⏳ Press and hold SPACE to speak...")
with keyboard.Listener(on_press=on_press, on_release=on_release) as listener:
# Wait for recording to complete or timeout
recording_done.wait(timeout=self.max_record_seconds)
if self._recording:
audio_result = self._stop_recording()
return audio_result
def transcribe(self, audio: np.ndarray) -> str:
start = time.perf_counter()
inputs = self.stt_processor(audio, sampling_rate=SAMPLE_RATE, return_tensors="pt")
input_features = inputs.input_features.to(self.device, dtype=self.dtype)
tokens = self.stt_model.generate(input_features)
text = self.stt_processor.batch_decode(tokens, skip_special_tokens=True)[0]
print(f"STT: {time.perf_counter() - start:.2f}s")
return text.strip()
def _create_dummy_images(self, batch_size: int = 1) -> tuple[list[torch.Tensor], list[torch.Tensor]]:
"""Create placeholder images for Pi0.5 when no camera is available."""
image_shape = (batch_size, 3, 224, 224)
dummy_image = torch.zeros(image_shape, dtype=torch.float32, device=self.device)
dummy_mask = torch.ones(batch_size, dtype=torch.bool, device=self.device)
return [dummy_image], [dummy_mask]
def _tokenize_prompt(self, text: str) -> tuple[torch.Tensor, torch.Tensor]:
"""Tokenize the user prompt for Pi0.5."""
prompt = f"User request: {text}\nRobot response:"
tokenized = self.tokenizer(
[prompt],
max_length=200,
truncation=True,
padding="max_length",
return_tensors="pt",
)
tokens = tokenized["input_ids"].to(self.device)
masks = tokenized["attention_mask"].to(self.device, dtype=torch.bool)
return tokens, masks
def generate_response(self, user_text: str) -> str:
"""Generate robot utterance using Pi0.5's language generation."""
start = time.perf_counter()
images, img_masks = self._create_dummy_images()
tokens, masks = self._tokenize_prompt(user_text)
with torch.no_grad():
generated_tokens = self.pi05_model._generate_subtask_tokens(
images=images,
img_masks=img_masks,
tokens=tokens,
masks=masks,
tokenizer=self.tokenizer,
max_length=self.max_response_tokens,
device=self.device,
)
# Decode generated tokens
valid_tokens = generated_tokens[0][generated_tokens[0] != 0]
response = self.tokenizer.decode(valid_tokens, skip_special_tokens=True)
# Extract utterance if marked with special tokens
response = self._extract_utterance(response)
print(f"Pi0.5: {time.perf_counter() - start:.2f}s")
return response.strip()
def _extract_utterance(self, text: str) -> str:
"""Extract utterance from between <utterance> tokens if present."""
pattern = r"<utterance>(.*?)</utterance>"
match = re.search(pattern, text, re.DOTALL)
if match:
return match.group(1).strip()
return text
def speak(self, text: str):
start = time.perf_counter()
if self.tts_type == "kokoro":
generator = self.tts_pipeline(text, voice=self.tts_voice)
audio_chunks = [audio for _, _, audio in generator]
if audio_chunks:
audio = np.concatenate(audio_chunks)
sd.play(audio, 24000)
sd.wait()
else:
subprocess.run(["say", text], check=True)
print(f"TTS: {time.perf_counter() - start:.2f}s")
def run(self):
print("=" * 50)
print("Pi0.5 Voice Assistant")
print("=" * 50)
print("• Hold SPACE to record your voice command")
print("• Release SPACE when done speaking")
print("• Press Ctrl+C to exit")
print("=" * 50)
while True:
try:
audio = self.wait_for_spacebar()
if audio is None:
print("(no audio captured)\n")
continue
user_text = self.transcribe(audio)
if not user_text:
print("(no speech detected)\n")
continue
print(f"You: {user_text}")
response = self.generate_response(user_text)
print(f"Robot: {response}\n")
self.speak(response)
except KeyboardInterrupt:
print("\nGoodbye!")
break
def main():
parser = argparse.ArgumentParser(description="Pi0.5 Voice Assistant")
parser.add_argument(
"--pretrained_path",
type=str,
default=None,
help="Path to pretrained Pi0.5 model (optional)",
)
parser.add_argument(
"--max_response_tokens",
type=int,
default=100,
help="Maximum tokens in generated response",
)
parser.add_argument(
"--max_record_seconds",
type=float,
default=30.0,
help="Maximum recording duration in seconds",
)
args = parser.parse_args()
assistant = Pi05VoiceAssistant(
pretrained_path=args.pretrained_path,
max_response_tokens=args.max_response_tokens,
max_record_seconds=args.max_record_seconds,
)
assistant.run()
if __name__ == "__main__":
main()

26
fast_tokenizer_local/metadata.json Normal file
View File

@@ -0,0 +1,26 @@
{
"repo_id": "local",
"vocab_size": 1024,
"scale": 10.0,
"encoded_dims": "0:15",
"encoded_dim_ranges": [
[
0,
15
]
],
"total_encoded_dims": 15,
"delta_dims": null,
"delta_dim_list": null,
"use_delta_transform": false,
"state_key": "observation.state",
"action_horizon": 50,
"num_training_chunks": 4900,
"compression_stats": {
"compression_ratio": 15.85791309863622,
"mean_token_length": 47.295,
"p99_token_length": 90.0,
"min_token_length": 9.0,
"max_token_length": 109.0
}
}

158
fast_tokenizer_local/processing_action_tokenizer.py Normal file
View File

@@ -0,0 +1,158 @@
import logging
from typing import ClassVar
import numpy as np
from scipy.fft import dct
from scipy.fft import idct
from tokenizers import ByteLevelBPETokenizer
from tokenizers.trainers import BpeTrainer
from transformers import PreTrainedTokenizerFast
from transformers.processing_utils import ProcessorMixin
class UniversalActionProcessor(ProcessorMixin):
attributes: ClassVar[list[str]] = ["bpe_tokenizer"]
bpe_tokenizer_class: str = "AutoTokenizer"
def __init__(
self,
bpe_tokenizer: PreTrainedTokenizerFast,
scale: float = 10,
vocab_size: int = 1024,
min_token: int = 0,
*,
action_dim: int | None = None,
time_horizon: int | None = None,
):
self.scale = scale
self.vocab_size = vocab_size
self.min_token = min_token
# Action horizon and dimension needed during decoding. These can be specified
# in three ways (in order of priority):
# 1. passed in as kwargs to decode()
# 2. in the constructor
# 3. cached from the last time decode() was called
self.time_horizon = time_horizon
self.action_dim = action_dim
self.called_time_horizon = time_horizon
self.called_action_dim = action_dim
super().__init__(bpe_tokenizer)
def __call__(self, action_chunk: np.array) -> np.array:
assert action_chunk.ndim <= 3, "Only 3 dimensions supported: [batch, timesteps, action_dim]"
if action_chunk.ndim == 2:
action_chunk = action_chunk[None, ...]
# Cache the time horizon and action dimension for decoding
self.called_time_horizon = action_chunk.shape[-2]
self.called_action_dim = action_chunk.shape[-1]
dct_coeff = dct(action_chunk, axis=1, norm="ortho")
dct_coeff = np.around(dct_coeff * self.scale)
tokens = []
for elem in dct_coeff:
token_str = "".join(map(chr, np.maximum(elem.flatten() - self.min_token, 0).astype(int)))
tokens.append(self.bpe_tokenizer(token_str)["input_ids"])
return tokens
def decode(
self,
tokens: list[list[int]],
*,
time_horizon: int | None = None,
action_dim: int | None = None,
) -> np.array:
self.time_horizon = time_horizon or self.time_horizon or self.called_time_horizon
self.action_dim = action_dim or self.action_dim or self.called_action_dim
# Cache the time horizon and action dimension for the next call
self.called_time_horizon = self.time_horizon
self.called_action_dim = self.action_dim
assert (
self.time_horizon is not None and self.action_dim is not None
), "Tokenizer not initialized, call encode() once or pass in time_horizon and action_dim."
decoded_actions = []
for token in tokens:
try:
decoded_tokens = self.bpe_tokenizer.decode(token)
decoded_dct_coeff = np.array(list(map(ord, decoded_tokens))) + self.min_token
decoded_dct_coeff = decoded_dct_coeff.reshape(-1, self.action_dim)
assert (
decoded_dct_coeff.shape
== (
self.time_horizon,
self.action_dim,
)
), f"Decoded DCT coefficients have shape {decoded_dct_coeff.shape}, expected ({self.time_horizon}, {self.action_dim})"
except Exception as e:
print(f"Error decoding tokens: {e}")
print(f"Tokens: {token}")
decoded_dct_coeff = np.zeros((self.time_horizon, self.action_dim))
decoded_actions.append(idct(decoded_dct_coeff / self.scale, axis=0, norm="ortho"))
return np.stack(decoded_actions)
@classmethod
def fit(
cls,
action_data: list[np.array],
scale: float = 10,
vocab_size: int = 1024,
*,
time_horizon: int | None = None,
action_dim: int | None = None,
) -> "UniversalActionProcessor":
# Run DCT over all inputs
dct_tokens = [dct(a, axis=0, norm="ortho").flatten() for a in action_data]
# Quantize and find min token
max_token = int(np.around(np.concatenate(dct_tokens) * scale).max())
min_token = int(np.around(np.concatenate(dct_tokens) * scale).min())
min_vocab_size = max_token - min_token
assert (
min_vocab_size <= vocab_size
), f"Vocab size {vocab_size} is too small for the range of tokens {min_vocab_size}"
if min_vocab_size + 100 > vocab_size:
logging.warning(
f"Initial alphabet size {min_vocab_size} is almost as large as the vocab"
f"size {vocab_size}, consider increasing vocab size"
)
# Make token iterator for BPE training
def _token_iter():
for tokens in dct_tokens:
rounded_tokens = np.around(tokens * scale) - min_token
rounded_tokens = rounded_tokens.astype(int)
string = "".join(map(chr, rounded_tokens))
yield string
# Train BPE tokenizer
bpe = ByteLevelBPETokenizer()
# Set up the entire range of possible tokens as the initial alphabet
alphabet = [chr(i) for i in range(max_token - min_token + 1)]
trainer = BpeTrainer(
vocab_size=vocab_size,
min_frequency=2,
show_progress=True,
special_tokens=[],
initial_alphabet=alphabet,
max_token_length=10000,
)
# Train the inner tokenizer (don't use ByteLevelBPETokenizer.train_from_iterator()
# because it doesn't support custom alphabets)
bpe._tokenizer.train_from_iterator(_token_iter(), trainer=trainer)
return cls(
PreTrainedTokenizerFast(tokenizer_object=bpe, clean_up_tokenization_spaces=False),
scale=scale,
vocab_size=vocab_size,
min_token=min_token,
time_horizon=time_horizon,
action_dim=action_dim,
)

11
fast_tokenizer_local/processor_config.json Normal file
View File

@@ -0,0 +1,11 @@
{
"action_dim": 15,
"auto_map": {
"AutoProcessor": "processing_action_tokenizer.UniversalActionProcessor"
},
"min_token": -71,
"processor_class": "UniversalActionProcessor",
"scale": 10.0,
"time_horizon": 50,
"vocab_size": 1024
}

1
fast_tokenizer_local/special_tokens_map.json Normal file
View File

@@ -0,0 +1 @@
{}

4387
fast_tokenizer_local/tokenizer.json Normal file
View File

File diff suppressed because it is too large Load Diff

11
fast_tokenizer_local/tokenizer_config.json Normal file
View File

@@ -0,0 +1,11 @@
{
"added_tokens_decoder": {},
"auto_map": {
"AutoProcessor": "processing_action_tokenizer.UniversalActionProcessor"
},
"clean_up_tokenization_spaces": false,
"extra_special_tokens": {},
"model_max_length": 1000000000000000019884624838656,
"processor_class": "UniversalActionProcessor",
"tokenizer_class": "PreTrainedTokenizerFast"
}

14
pyproject.toml
View File

@@ -25,7 +25,7 @@ discord = "https://discord.gg/s3KuuzsPFb"
[project]
name = "lerobot"
version = "0.4.2"
version = "0.4.3"
description = "🤗 LeRobot: State-of-the-art Machine Learning for Real-World Robotics in Pytorch"
readme = "README.md"
license = { text = "Apache-2.0" }
@@ -107,6 +107,10 @@ dynamixel = ["dynamixel-sdk>=3.7.31,<3.9.0"]
gamepad = ["lerobot[pygame-dep]", "hidapi>=0.14.0,<0.15.0"]
hopejr = ["lerobot[feetech]", "lerobot[pygame-dep]"]
lekiwi = ["lerobot[feetech]", "pyzmq>=26.2.1,<28.0.0"]
unitree_g1 = [
"pyzmq>=26.2.1,<28.0.0",
"onnxruntime>=1.16.0"
]
reachy2 = ["reachy2_sdk>=1.0.14,<1.1.0"]
kinematics = ["lerobot[placo-dep]"]
intelrealsense = [
@@ -129,6 +133,7 @@ groot = [
"ninja>=1.11.1,<2.0.0",
"flash-attn>=2.5.9,<3.0.0 ; sys_platform != 'darwin'"
]
xvla = ["lerobot[transformers-dep]"]
hilserl = ["lerobot[transformers-dep]", "gym-hil>=0.1.13,<0.2.0", "lerobot[grpcio-dep]", "lerobot[placo-dep]"]
# Features
@@ -157,6 +162,7 @@ all = [
"lerobot[pi]",
"lerobot[smolvla]",
# "lerobot[groot]", TODO(Steven): Gr00t requires specific installation instructions for flash-attn
"lerobot[xvla]",
"lerobot[hilserl]",
"lerobot[async]",
"lerobot[dev]",
@@ -356,9 +362,9 @@ ignore_errors = false
# module = "lerobot.async_inference.*"
# ignore_errors = false
# [[tool.mypy.overrides]]
# module = "lerobot.transport.*"
# ignore_errors = false
[[tool.mypy.overrides]]
module = "lerobot.transport.*"
ignore_errors = false
# [[tool.mypy.overrides]]
# module = "lerobot.scripts.*"

75
src/lerobot/datasets/aggregate.py
View File

@@ -136,21 +136,40 @@ def update_meta_data(
df["_orig_chunk"] = df[orig_chunk_col].copy()
df["_orig_file"] = df[orig_file_col].copy()
# Update chunk and file indices to point to destination
# Get mappings for this video key
src_to_offset = video_idx.get("src_to_offset", {})
src_to_dst = video_idx.get("src_to_dst", {})
# Apply per-source-file mappings
if src_to_dst:
# Map each episode to its correct destination file and apply offset
for idx in df.index:
# Convert to Python int to avoid numpy type mismatch in dict lookup
src_key = (int(df.at[idx, "_orig_chunk"]), int(df.at[idx, "_orig_file"]))
# Get destination chunk/file for this source file
dst_chunk, dst_file = src_to_dst.get(src_key, (video_idx["chunk"], video_idx["file"]))
df.at[idx, orig_chunk_col] = dst_chunk
df.at[idx, orig_file_col] = dst_file
# Apply timestamp offset
offset = src_to_offset.get(src_key, 0)
df.at[idx, f"videos/{key}/from_timestamp"] += offset
df.at[idx, f"videos/{key}/to_timestamp"] += offset
elif src_to_offset:
# Fallback: use same destination for all, but apply per-file offsets
df[orig_chunk_col] = video_idx["chunk"]
df[orig_file_col] = video_idx["file"]
# Apply per-source-file timestamp offsets
src_to_offset = video_idx.get("src_to_offset", {})
if src_to_offset:
# Apply offset based on original source file
for idx in df.index:
src_key = (df.at[idx, "_orig_chunk"], df.at[idx, "_orig_file"])
# Convert to Python int to avoid numpy type mismatch in dict lookup
src_key = (int(df.at[idx, "_orig_chunk"]), int(df.at[idx, "_orig_file"]))
offset = src_to_offset.get(src_key, 0)
df.at[idx, f"videos/{key}/from_timestamp"] += offset
df.at[idx, f"videos/{key}/to_timestamp"] += offset
else:
# Fallback to simple offset (for backward compatibility)
df[orig_chunk_col] = video_idx["chunk"]
df[orig_file_col] = video_idx["file"]
df[f"videos/{key}/from_timestamp"] = (
df[f"videos/{key}/from_timestamp"] + video_idx["latest_duration"]
)
@@ -268,6 +287,12 @@ def aggregate_videos(src_meta, dst_meta, videos_idx, video_files_size_in_mb, chu
videos_idx[key]["episode_duration"] = 0
# Track offset for each source (chunk, file) pair
videos_idx[key]["src_to_offset"] = {}
# Track destination (chunk, file) for each source (chunk, file) pair
videos_idx[key]["src_to_dst"] = {}
# Initialize dst_file_durations if not present
# dst_file_durations tracks duration of each destination file
if "dst_file_durations" not in videos_idx[key]:
videos_idx[key]["dst_file_durations"] = {}
for key, video_idx in videos_idx.items():
unique_chunk_file_pairs = {
@@ -282,9 +307,13 @@ def aggregate_videos(src_meta, dst_meta, videos_idx, video_files_size_in_mb, chu
chunk_idx = video_idx["chunk"]
file_idx = video_idx["file"]
current_offset = video_idx["latest_duration"]
dst_file_durations = video_idx["dst_file_durations"]
for src_chunk_idx, src_file_idx in unique_chunk_file_pairs:
# Convert to Python int to ensure consistent dict keys
src_chunk_idx = int(src_chunk_idx)
src_file_idx = int(src_file_idx)
src_path = src_meta.root / DEFAULT_VIDEO_PATH.format(
video_key=key,
chunk_index=src_chunk_idx,
@@ -298,14 +327,17 @@ def aggregate_videos(src_meta, dst_meta, videos_idx, video_files_size_in_mb, chu
)
src_duration = get_video_duration_in_s(src_path)
dst_key = (chunk_idx, file_idx)
if not dst_path.exists():
# Store offset before incrementing
videos_idx[key]["src_to_offset"][(src_chunk_idx, src_file_idx)] = current_offset
# New destination file: offset is 0
videos_idx[key]["src_to_offset"][(src_chunk_idx, src_file_idx)] = 0
videos_idx[key]["src_to_dst"][(src_chunk_idx, src_file_idx)] = dst_key
dst_path.parent.mkdir(parents=True, exist_ok=True)
shutil.copy(str(src_path), str(dst_path))
# Track duration of this destination file
dst_file_durations[dst_key] = src_duration
videos_idx[key]["episode_duration"] += src_duration
current_offset += src_duration
continue
# Check file sizes before appending
@@ -313,10 +345,11 @@ def aggregate_videos(src_meta, dst_meta, videos_idx, video_files_size_in_mb, chu
dst_size = get_file_size_in_mb(dst_path)
if dst_size + src_size >= video_files_size_in_mb:
# Rotate to a new file, this source becomes start of new destination
# So its offset should be 0
videos_idx[key]["src_to_offset"][(src_chunk_idx, src_file_idx)] = 0
# Rotate to a new file - offset is 0
chunk_idx, file_idx = update_chunk_file_indices(chunk_idx, file_idx, chunk_size)
dst_key = (chunk_idx, file_idx)
videos_idx[key]["src_to_offset"][(src_chunk_idx, src_file_idx)] = 0
videos_idx[key]["src_to_dst"][(src_chunk_idx, src_file_idx)] = dst_key
dst_path = dst_meta.root / DEFAULT_VIDEO_PATH.format(
video_key=key,
chunk_index=chunk_idx,
@@ -324,16 +357,20 @@ def aggregate_videos(src_meta, dst_meta, videos_idx, video_files_size_in_mb, chu
)
dst_path.parent.mkdir(parents=True, exist_ok=True)
shutil.copy(str(src_path), str(dst_path))
# Reset offset for next file
current_offset = src_duration
# Track duration of this new destination file
dst_file_durations[dst_key] = src_duration
else:
# Append to existing video file - use current accumulated offset
videos_idx[key]["src_to_offset"][(src_chunk_idx, src_file_idx)] = current_offset
# Append to existing destination file
# Offset is the current duration of this destination file
current_dst_duration = dst_file_durations.get(dst_key, 0)
videos_idx[key]["src_to_offset"][(src_chunk_idx, src_file_idx)] = current_dst_duration
videos_idx[key]["src_to_dst"][(src_chunk_idx, src_file_idx)] = dst_key
concatenate_video_files(
[dst_path, src_path],
dst_path,
)
current_offset += src_duration
# Update duration of this destination file
dst_file_durations[dst_key] = current_dst_duration + src_duration
videos_idx[key]["episode_duration"] += src_duration

10
src/lerobot/datasets/image_writer.py
View File

@@ -110,8 +110,8 @@ def worker_thread_loop(queue: queue.Queue):
if item is None:
queue.task_done()
break
image_array, fpath = item
write_image(image_array, fpath)
image_array, fpath, compress_level = item
write_image(image_array, fpath, compress_level)
queue.task_done()
@@ -169,11 +169,13 @@ class AsyncImageWriter:
p.start()
self.processes.append(p)
def save_image(self, image: torch.Tensor | np.ndarray | PIL.Image.Image, fpath: Path):
def save_image(
self, image: torch.Tensor | np.ndarray | PIL.Image.Image, fpath: Path, compress_level: int = 1
):
if isinstance(image, torch.Tensor):
# Convert tensor to numpy array to minimize main process time
image = image.cpu().numpy()
self.queue.put((image, fpath))
self.queue.put((image, fpath, compress_level))
def wait_until_done(self):
self.queue.join()

87
src/lerobot/datasets/lerobot_dataset.py
View File

@@ -13,6 +13,7 @@
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
import concurrent.futures
import contextlib
import logging
import shutil
@@ -57,6 +58,7 @@ from lerobot.datasets.utils import (
load_nested_dataset,
load_stats,
load_tasks,
load_tasks_high_level,
update_chunk_file_indices,
validate_episode_buffer,
validate_frame,
@@ -160,6 +162,7 @@ class LeRobotDatasetMetadata:
self.info = load_info(self.root)
check_version_compatibility(self.repo_id, self._version, CODEBASE_VERSION)
self.tasks = load_tasks(self.root)
self.tasks_high_level = load_tasks_high_level(self.root)
self.episodes = load_episodes(self.root)
self.stats = load_stats(self.root)
@@ -539,6 +542,15 @@ class LeRobotDatasetMetadata:
return obj
def _encode_video_worker(video_key: str, episode_index: int, root: Path, fps: int) -> Path:
temp_path = Path(tempfile.mkdtemp(dir=root)) / f"{video_key}_{episode_index:03d}.mp4"
fpath = DEFAULT_IMAGE_PATH.format(image_key=video_key, episode_index=episode_index, frame_index=0)
img_dir = (root / fpath).parent
encode_video_frames(img_dir, temp_path, fps, overwrite=True)
shutil.rmtree(img_dir)
return temp_path
class LeRobotDataset(torch.utils.data.Dataset):
def __init__(
self,
@@ -1040,6 +1052,12 @@ class LeRobotDataset(torch.utils.data.Dataset):
# Add task as a string
task_idx = item["task_index"].item()
item["task"] = self.meta.tasks.iloc[task_idx].name
# Optionally add high level task index
if "task_index_high_level" in self.features:
high_level_task_idx = item["task_index_high_level"].item()
item["robot_utterance"] = self.meta.tasks_high_level.iloc[high_level_task_idx]["robot_utterance"]
item["user_prompt"] = self.meta.tasks_high_level.iloc[high_level_task_idx]["user_prompt"]
return item
def __repr__(self):
@@ -1071,6 +1089,7 @@ class LeRobotDataset(torch.utils.data.Dataset):
ep_buffer[key] = current_ep_idx if key == "episode_index" else []
return ep_buffer
# TODO(Steven): consider move this to utils
def _get_image_file_path(self, episode_index: int, image_key: str, frame_index: int) -> Path:
fpath = DEFAULT_IMAGE_PATH.format(
image_key=image_key, episode_index=episode_index, frame_index=frame_index
@@ -1080,13 +1099,15 @@ class LeRobotDataset(torch.utils.data.Dataset):
def _get_image_file_dir(self, episode_index: int, image_key: str) -> Path:
return self._get_image_file_path(episode_index, image_key, frame_index=0).parent
def _save_image(self, image: torch.Tensor | np.ndarray | PIL.Image.Image, fpath: Path) -> None:
def _save_image(
self, image: torch.Tensor | np.ndarray | PIL.Image.Image, fpath: Path, compress_level: int = 1
) -> None:
if self.image_writer is None:
if isinstance(image, torch.Tensor):
image = image.cpu().numpy()
write_image(image, fpath)
write_image(image, fpath, compress_level=compress_level)
else:
self.image_writer.save_image(image=image, fpath=fpath)
self.image_writer.save_image(image=image, fpath=fpath, compress_level=compress_level)
def add_frame(self, frame: dict) -> None:
"""
@@ -1124,14 +1145,19 @@ class LeRobotDataset(torch.utils.data.Dataset):
)
if frame_index == 0:
img_path.parent.mkdir(parents=True, exist_ok=True)
self._save_image(frame[key], img_path)
compress_level = 1 if self.features[key]["dtype"] == "video" else 6
self._save_image(frame[key], img_path, compress_level)
self.episode_buffer[key].append(str(img_path))
else:
self.episode_buffer[key].append(frame[key])
self.episode_buffer["size"] += 1
def save_episode(self, episode_data: dict | None = None) -> None:
def save_episode(
self,
episode_data: dict | None = None,
parallel_encoding: bool = True,
) -> None:
"""
This will save to disk the current episode in self.episode_buffer.
@@ -1143,6 +1169,8 @@ class LeRobotDataset(torch.utils.data.Dataset):
episode_data (dict | None, optional): Dict containing the episode data to save. If None, this will
save the current episode in self.episode_buffer, which is filled with 'add_frame'. Defaults to
None.
parallel_encoding (bool, optional): If True, encode videos in parallel using ProcessPoolExecutor.
Defaults to True on Linux, False on macOS as it tends to use all the CPU available already.
"""
episode_buffer = episode_data if episode_data is not None else self.episode_buffer
@@ -1179,6 +1207,38 @@ class LeRobotDataset(torch.utils.data.Dataset):
use_batched_encoding = self.batch_encoding_size > 1
if has_video_keys and not use_batched_encoding:
num_cameras = len(self.meta.video_keys)
if parallel_encoding and num_cameras > 1:
# TODO(Steven): Ideally we would like to control the number of threads per encoding such that:
# num_cameras * num_threads = (total_cpu -1)
with concurrent.futures.ProcessPoolExecutor(max_workers=num_cameras) as executor:
future_to_key = {
executor.submit(
_encode_video_worker,
video_key,
episode_index,
self.root,
self.fps,
): video_key
for video_key in self.meta.video_keys
}
results = {}
for future in concurrent.futures.as_completed(future_to_key):
video_key = future_to_key[future]
try:
temp_path = future.result()
results[video_key] = temp_path
except Exception as exc:
logging.error(f"Video encoding failed for {video_key}: {exc}")
raise exc
for video_key in self.meta.video_keys:
temp_path = results[video_key]
ep_metadata.update(
self._save_episode_video(video_key, episode_index, temp_path=temp_path)
)
else:
for video_key in self.meta.video_keys:
ep_metadata.update(self._save_episode_video(video_key, episode_index))
@@ -1345,9 +1405,18 @@ class LeRobotDataset(torch.utils.data.Dataset):
return metadata
def _save_episode_video(self, video_key: str, episode_index: int) -> dict:
def _save_episode_video(
self,
video_key: str,
episode_index: int,
temp_path: Path | None = None,
) -> dict:
# Encode episode frames into a temporary video
if temp_path is None:
ep_path = self._encode_temporary_episode_video(video_key, episode_index)
else:
ep_path = temp_path
ep_size_in_mb = get_file_size_in_mb(ep_path)
ep_duration_in_s = get_video_duration_in_s(ep_path)
@@ -1465,11 +1534,7 @@ class LeRobotDataset(torch.utils.data.Dataset):
Note: `encode_video_frames` is a blocking call. Making it asynchronous shouldn't speedup encoding,
since video encoding with ffmpeg is already using multithreading.
"""
temp_path = Path(tempfile.mkdtemp(dir=self.root)) / f"{video_key}_{episode_index:03d}.mp4"
img_dir = self._get_image_file_dir(episode_index, video_key)
encode_video_frames(img_dir, temp_path, self.fps, overwrite=True)
shutil.rmtree(img_dir)
return temp_path
return _encode_video_worker(video_key, episode_index, self.root, self.fps)
@classmethod
def create(

6
src/lerobot/datasets/utils.py
View File

@@ -49,7 +49,7 @@ from lerobot.utils.utils import SuppressProgressBars, is_valid_numpy_dtype_strin
DEFAULT_CHUNK_SIZE = 1000 # Max number of files per chunk
DEFAULT_DATA_FILE_SIZE_IN_MB = 100 # Max size per file
DEFAULT_VIDEO_FILE_SIZE_IN_MB = 500 # Max size per file
DEFAULT_VIDEO_FILE_SIZE_IN_MB = 200 # Max size per file
INFO_PATH = "meta/info.json"
STATS_PATH = "meta/stats.json"
@@ -60,6 +60,7 @@ VIDEO_DIR = "videos"
CHUNK_FILE_PATTERN = "chunk-{chunk_index:03d}/file-{file_index:03d}"
DEFAULT_TASKS_PATH = "meta/tasks.parquet"
DEFAULT_TASKS_HIGH_LEVEL_PATH = "meta/tasks_high_level.parquet"
DEFAULT_EPISODES_PATH = EPISODES_DIR + "/" + CHUNK_FILE_PATTERN + ".parquet"
DEFAULT_DATA_PATH = DATA_DIR + "/" + CHUNK_FILE_PATTERN + ".parquet"
DEFAULT_VIDEO_PATH = VIDEO_DIR + "/{video_key}/" + CHUNK_FILE_PATTERN + ".mp4"
@@ -352,6 +353,9 @@ def load_tasks(local_dir: Path) -> pandas.DataFrame:
tasks = pd.read_parquet(local_dir / DEFAULT_TASKS_PATH)
return tasks
def load_tasks_high_level(local_dir: Path) -> pandas.DataFrame:
tasks = pd.read_parquet(local_dir / DEFAULT_TASKS_HIGH_LEVEL_PATH)
return tasks
def write_episodes(episodes: Dataset, local_dir: Path) -> None:
"""Write episode metadata to a parquet file in the LeRobot v3.0 format.

4
src/lerobot/datasets/video_utils.py
View File

@@ -311,6 +311,7 @@ def encode_video_frames(
fast_decode: int = 0,
log_level: int | None = av.logging.ERROR,
overwrite: bool = False,
preset: int | None = None,
) -> None:
"""More info on ffmpeg arguments tuning on `benchmark/video/README.md`"""
# Check encoder availability
@@ -359,6 +360,9 @@ def encode_video_frames(
value = f"fast-decode={fast_decode}" if vcodec == "libsvtav1" else "fastdecode"
video_options[key] = value
if vcodec == "libsvtav1":
video_options["preset"] = str(preset) if preset is not None else "12"
# Set logging level
if log_level is not None:
# "While less efficient, it is generally preferable to modify logging with Python's logging"

3
src/lerobot/envs/configs.py
View File

@@ -245,7 +245,7 @@ class HILSerlRobotEnvConfig(EnvConfig):
class LiberoEnv(EnvConfig):
task: str = "libero_10" # can also choose libero_spatial, libero_object, etc.
fps: int = 30
episode_length: int = 520
episode_length: int | None = None
obs_type: str = "pixels_agent_pos"
render_mode: str = "rgb_array"
camera_name: str = "agentview_image,robot0_eye_in_hand_image"
@@ -272,6 +272,7 @@ class LiberoEnv(EnvConfig):
LIBERO_KEY_PIXELS_EYE_IN_HAND: f"{OBS_IMAGES}.image2",
}
)
control_mode: str = "relative" # or "absolute"
def __post_init__(self):
if self.obs_type == "pixels":

9
src/lerobot/envs/factory.py
View File

@@ -19,8 +19,10 @@ from typing import Any
import gymnasium as gym
from gymnasium.envs.registration import registry as gym_registry
from lerobot.configs.policies import PreTrainedConfig
from lerobot.envs.configs import AlohaEnv, EnvConfig, LiberoEnv, PushtEnv
from lerobot.envs.utils import _call_make_env, _download_hub_file, _import_hub_module, _normalize_hub_result
from lerobot.policies.xvla.configuration_xvla import XVLAConfig
from lerobot.processor import ProcessorStep
from lerobot.processor.env_processor import LiberoProcessorStep
from lerobot.processor.pipeline import PolicyProcessorPipeline
@@ -39,6 +41,7 @@ def make_env_config(env_type: str, **kwargs) -> EnvConfig:
def make_env_pre_post_processors(
env_cfg: EnvConfig,
policy_cfg: PreTrainedConfig,
) -> tuple[
PolicyProcessorPipeline[dict[str, Any], dict[str, Any]],
PolicyProcessorPipeline[dict[str, Any], dict[str, Any]],
@@ -61,6 +64,10 @@ def make_env_pre_post_processors(
# Preprocessor and Postprocessor steps are Identity for most environments
preprocessor_steps: list[ProcessorStep] = []
postprocessor_steps: list[ProcessorStep] = []
if isinstance(policy_cfg, XVLAConfig):
from lerobot.policies.xvla.processor_xvla import make_xvla_libero_pre_post_processors
return make_xvla_libero_pre_post_processors()
# For LIBERO environments, add the LiberoProcessorStep to preprocessor
if isinstance(env_cfg, LiberoEnv) or "libero" in env_cfg.type:
@@ -136,6 +143,8 @@ def make_env(
init_states=cfg.init_states,
gym_kwargs=cfg.gym_kwargs,
env_cls=env_cls,
control_mode=cfg.control_mode,
episode_length=cfg.episode_length,
)
elif "metaworld" in cfg.type:
from lerobot.envs.metaworld import create_metaworld_envs

31
src/lerobot/envs/libero.py
View File

@@ -80,10 +80,7 @@ def get_libero_dummy_action():
return [0, 0, 0, 0, 0, 0, -1]
OBS_STATE_DIM = 8
ACTION_DIM = 7
AGENT_POS_LOW = -1000.0
AGENT_POS_HIGH = 1000.0
ACTION_LOW = -1.0
ACTION_HIGH = 1.0
TASK_SUITE_MAX_STEPS: dict[str, int] = {
@@ -103,6 +100,7 @@ class LiberoEnv(gym.Env):
task_suite: Any,
task_id: int,
task_suite_name: str,
episode_length: int | None = None,
camera_name: str | Sequence[str] = "agentview_image,robot0_eye_in_hand_image",
obs_type: str = "pixels",
render_mode: str = "rgb_array",
@@ -114,6 +112,7 @@ class LiberoEnv(gym.Env):
episode_index: int = 0,
camera_name_mapping: dict[str, str] | None = None,
num_steps_wait: int = 10,
control_mode: str = "relative",
):
super().__init__()
self.task_id = task_id
@@ -141,14 +140,19 @@ class LiberoEnv(gym.Env):
self.camera_name_mapping = camera_name_mapping
self.num_steps_wait = num_steps_wait
self.episode_index = episode_index
self.episode_length = episode_length
# Load once and keep
self._init_states = get_task_init_states(task_suite, self.task_id) if self.init_states else None
self._init_state_id = self.episode_index # tie each sub-env to a fixed init state
self._env = self._make_envs_task(task_suite, self.task_id)
default_steps = 500
self._max_episode_steps = TASK_SUITE_MAX_STEPS.get(task_suite_name, default_steps)
self._max_episode_steps = (
TASK_SUITE_MAX_STEPS.get(task_suite_name, default_steps)
if self.episode_length is None
else self.episode_length
)
self.control_mode = control_mode
images = {}
for cam in self.camera_name:
images[self.camera_name_mapping[cam]] = spaces.Box(
@@ -296,6 +300,15 @@ class LiberoEnv(gym.Env):
# Increasing this value can improve determinism and reproducibility across resets.
for _ in range(self.num_steps_wait):
raw_obs, _, _, _ = self._env.step(get_libero_dummy_action())
if self.control_mode == "absolute":
for robot in self._env.robots:
robot.controller.use_delta = False
elif self.control_mode == "relative":
for robot in self._env.robots:
robot.controller.use_delta = True
else:
raise ValueError(f"Invalid control mode: {self.control_mode}")
observation = self._format_raw_obs(raw_obs)
info = {"is_success": False}
return observation, info
@@ -341,8 +354,10 @@ def _make_env_fns(
task_id: int,
n_envs: int,
camera_names: list[str],
episode_length: int | None,
init_states: bool,
gym_kwargs: Mapping[str, Any],
control_mode: str,
) -> list[Callable[[], LiberoEnv]]:
"""Build n_envs factory callables for a single (suite, task_id)."""
@@ -354,7 +369,9 @@ def _make_env_fns(
task_suite_name=suite_name,
camera_name=camera_names,
init_states=init_states,
episode_length=episode_length,
episode_index=episode_index,
control_mode=control_mode,
**local_kwargs,
)
@@ -374,6 +391,8 @@ def create_libero_envs(
camera_name: str | Sequence[str] = "agentview_image,robot0_eye_in_hand_image",
init_states: bool = True,
env_cls: Callable[[Sequence[Callable[[], Any]]], Any] | None = None,
control_mode: str = "relative",
episode_length: int | None = None,
) -> dict[str, dict[int, Any]]:
"""
Create vectorized LIBERO environments with a consistent return shape.
@@ -415,12 +434,14 @@ def create_libero_envs(
for tid in selected:
fns = _make_env_fns(
suite=suite,
episode_length=episode_length,
suite_name=suite_name,
task_id=tid,
n_envs=n_envs,
camera_names=camera_names,
init_states=init_states,
gym_kwargs=gym_kwargs,
control_mode=control_mode,
)
out[suite_name][tid] = env_cls(fns)
print(f"Built vec env | suite={suite_name} | task_id={tid} | n_envs={n_envs}")

101
src/lerobot/optim/optimizers.py
View File

@@ -104,6 +104,107 @@ class SGDConfig(OptimizerConfig):
return torch.optim.SGD(params, **kwargs)
@OptimizerConfig.register_subclass("xvla-adamw")
@dataclass
class XVLAAdamWConfig(OptimizerConfig):
"""Custom AdamW optimizer for XVLA with differential learning rates.
The Vision-Language Model (VLM) is trained with 1/10 of the base learning rate
for stable optimization, while all other components use the full LR.
This LR ratio is crucial for achieving strong and stable finetuning performance.
Soft-prompts can optionally use a separate learning rate with warm-up support.
Set `soft_prompt_lr_scale` to a value < 1.0 (e.g., 0.1) to start soft-prompts
at a lower LR. Combine with a warmup scheduler for optimal results.
Note:
Completely matching official reported performance may require an additional
warm-up LR schedule for soft-prompts, which can bring minor improvements.
When `soft_prompt_warmup_lr_scale` is set, soft-prompts start at
`lr * soft_prompt_warmup_lr_scale` and should be warmed up via the scheduler.
Parameter Groups:
- Group 0 (vlm): VLM parameters at lr * 0.1, weight_decay * 0.1
- Group 1 (soft_prompts): Soft-prompt parameters at lr * soft_prompt_lr_scale
- Group 2 (other): All other parameters at full lr
"""
lr: float = 1e-4
betas: tuple[float, float] = (0.9, 0.99)
eps: float = 1e-8
weight_decay: float = 0.0
grad_clip_norm: float = 10.0
# Soft-prompt specific settings
soft_prompt_lr_scale: float = 1.0 # Scale factor for soft-prompt LR (1.0 = same as base LR)
soft_prompt_warmup_lr_scale: float | None = None # If set, start soft-prompts at this scale (e.g., 0.01)
def build(self, params: dict) -> torch.optim.Optimizer:
"""
Build AdamW optimizer with differential learning rates.
Expects `named_parameters()` as input (dict of name -> param).
Applies:
- lr * 0.1 for all VLM-related parameters
- lr * soft_prompt_lr_scale for soft-prompt parameters (with optional warmup)
- full lr for all other parameters
Args:
params: Dictionary of parameter names to parameters (from named_parameters())
Returns:
AdamW optimizer with parameter groups for VLM, soft-prompts, and other components
"""
assert isinstance(params, dict), "Custom LR optimizer requires `named_parameters()` as inputs."
vlm_group, soft_prompt_group, other_group = [], [], []
for name, p in params.items():
if not p.requires_grad:
continue
if "vlm" in name.lower():
vlm_group.append(p)
elif "soft_prompt" in name.lower():
soft_prompt_group.append(p)
else:
other_group.append(p)
# Determine soft-prompt LR
soft_prompt_lr = self.lr * self.soft_prompt_lr_scale
if self.soft_prompt_warmup_lr_scale is not None:
# Start at warmup scale, scheduler will warm up to soft_prompt_lr
soft_prompt_lr = self.lr * self.soft_prompt_warmup_lr_scale
param_groups = [
{
"params": vlm_group,
"lr": self.lr * 0.1,
"weight_decay": self.weight_decay * 0.1,
"name": "vlm",
},
{
"params": soft_prompt_group,
"lr": soft_prompt_lr,
"weight_decay": self.weight_decay,
"name": "soft_prompts",
},
{
"params": other_group,
"lr": self.lr,
"weight_decay": self.weight_decay,
"name": "other",
},
]
# Filter out empty groups
param_groups = [g for g in param_groups if len(g["params"]) > 0]
return torch.optim.AdamW(
param_groups,
betas=self.betas,
eps=self.eps,
)
@OptimizerConfig.register_subclass("multi_adam")
@dataclass
class MultiAdamConfig(OptimizerConfig):

2
src/lerobot/policies/__init__.py
View File

@@ -21,6 +21,7 @@ from .smolvla.configuration_smolvla import SmolVLAConfig as SmolVLAConfig
from .smolvla.processor_smolvla import SmolVLANewLineProcessor
from .tdmpc.configuration_tdmpc import TDMPCConfig as TDMPCConfig
from .vqbet.configuration_vqbet import VQBeTConfig as VQBeTConfig
from .xvla.configuration_xvla import XVLAConfig as XVLAConfig
__all__ = [
"ACTConfig",
@@ -31,4 +32,5 @@ __all__ = [
"TDMPCConfig",
"VQBeTConfig",
"GrootConfig",
"XVLAConfig",
]

99
src/lerobot/policies/factory.py
View File

@@ -16,6 +16,7 @@
from __future__ import annotations
import importlib
import logging
from typing import Any, TypedDict
@@ -40,6 +41,7 @@ from lerobot.policies.smolvla.configuration_smolvla import SmolVLAConfig
from lerobot.policies.tdmpc.configuration_tdmpc import TDMPCConfig
from lerobot.policies.utils import validate_visual_features_consistency
from lerobot.policies.vqbet.configuration_vqbet import VQBeTConfig
from lerobot.policies.xvla.configuration_xvla import XVLAConfig
from lerobot.processor import PolicyAction, PolicyProcessorPipeline
from lerobot.processor.converters import (
batch_to_transition,
@@ -107,8 +109,15 @@ def get_policy_class(name: str) -> type[PreTrainedPolicy]:
from lerobot.policies.groot.modeling_groot import GrootPolicy
return GrootPolicy
elif name == "xvla":
from lerobot.policies.xvla.modeling_xvla import XVLAPolicy
return XVLAPolicy
else:
raise NotImplementedError(f"Policy with name {name} is not implemented.")
try:
return _get_policy_cls_from_policy_name(name=name)
except Exception as e:
raise ValueError(f"Policy type '{name}' is not available.") from e
def make_policy_config(policy_type: str, **kwargs) -> PreTrainedConfig:
@@ -150,8 +159,14 @@ def make_policy_config(policy_type: str, **kwargs) -> PreTrainedConfig:
return RewardClassifierConfig(**kwargs)
elif policy_type == "groot":
return GrootConfig(**kwargs)
elif policy_type == "xvla":
return XVLAConfig(**kwargs)
else:
raise ValueError(f"Policy type '{policy_type}' is not available.")
try:
config_cls = PreTrainedConfig.get_choice_class(policy_type)
return config_cls(**kwargs)
except Exception as e:
raise ValueError(f"Policy type '{policy_type}' is not available.") from e
class ProcessorConfigKwargs(TypedDict, total=False):
@@ -329,9 +344,24 @@ def make_pre_post_processors(
config=policy_cfg,
dataset_stats=kwargs.get("dataset_stats"),
)
elif isinstance(policy_cfg, XVLAConfig):
from lerobot.policies.xvla.processor_xvla import (
make_xvla_pre_post_processors,
)
processors = make_xvla_pre_post_processors(
config=policy_cfg,
dataset_stats=kwargs.get("dataset_stats"),
)
else:
raise NotImplementedError(f"Processor for policy type '{policy_cfg.type}' is not implemented.")
try:
processors = _make_processors_from_policy_config(
config=policy_cfg,
dataset_stats=kwargs.get("dataset_stats"),
)
except Exception as e:
raise ValueError(f"Processor for policy type '{policy_cfg.type}' is not implemented.") from e
return processors
@@ -400,7 +430,6 @@ def make_policy(
raise ValueError("env_cfg cannot be None when ds_meta is not provided")
features = env_to_policy_features(env_cfg)
if not cfg.output_features:
cfg.output_features = {key: ft for key, ft in features.items() if ft.type is FeatureType.ACTION}
if not cfg.input_features:
cfg.input_features = {key: ft for key, ft in features.items() if key not in cfg.output_features}
@@ -425,3 +454,65 @@ def make_policy(
# TODO: (jadechoghari) - add a check_state(cfg, features) and check_action(cfg, features)
return policy
def _get_policy_cls_from_policy_name(name: str) -> type[PreTrainedConfig]:
"""Get policy class from its registered name using dynamic imports.
This is used as a helper function to import policies from 3rd party lerobot plugins.
Args:
name: The name of the policy.
Returns:
The policy class corresponding to the given name.
"""
if name not in PreTrainedConfig.get_known_choices():
raise ValueError(
f"Unknown policy name '{name}'. Available policies: {PreTrainedConfig.get_known_choices()}"
)
config_cls = PreTrainedConfig.get_choice_class(name)
config_cls_name = config_cls.__name__
model_name = config_cls_name.removesuffix("Config") # e.g., DiffusionConfig -> Diffusion
if model_name == config_cls_name:
raise ValueError(
f"The config class name '{config_cls_name}' does not follow the expected naming convention."
f"Make sure it ends with 'Config'!"
)
cls_name = model_name + "Policy" # e.g., DiffusionConfig -> DiffusionPolicy
module_path = config_cls.__module__.replace(
"configuration_", "modeling_"
) # e.g., configuration_diffusion -> modeling_diffusion
module = importlib.import_module(module_path)
policy_cls = getattr(module, cls_name)
return policy_cls
def _make_processors_from_policy_config(
config: PreTrainedConfig,
dataset_stats: dict[str, dict[str, torch.Tensor]] | None = None,
) -> tuple[Any, Any]:
"""Create pre- and post-processors from a policy configuration using dynamic imports.
This is used as a helper function to import processor factories from 3rd party lerobot plugins.
Args:
config: The policy configuration object.
dataset_stats: Dataset statistics for normalization.
Returns:
A tuple containing the input (pre-processor) and output (post-processor) pipelines.
"""
policy_type = config.type
function_name = f"make_{policy_type}_pre_post_processors"
module_path = config.__class__.__module__.replace(
"configuration_", "processor_"
) # e.g., configuration_diffusion -> processor_diffusion
logging.debug(
f"Instantiating pre/post processors using function '{function_name}' from module '{module_path}'"
)
module = importlib.import_module(module_path)
function = getattr(module, function_name)
return function(config, dataset_stats=dataset_stats)

196
src/lerobot/policies/pi05/README_TOKENIZER.md Normal file
View File

@@ -0,0 +1,196 @@
# FAST Tokenizer Training for LeRobotDataset
This directory contains tools for training a FAST (Factorized Action Sequence Tokenizer) on LeRobot datasets.
## Files
- **`train_fast_tokenizer.py`**: Main training script (refactored for LeRobotDataset)
- **`train_fast_tokenizer_example.md`**: Usage examples and parameter documentation
- **`MIGRATION_NOTES.md`**: Migration guide from B1K to LeRobotDataset
## Quick Start
```bash
# Basic usage
python train_fast_tokenizer.py \
--repo_id "lerobot/aloha_sim_insertion_human" \
--action_horizon 10 \
--encoded_dims "0:14"
# With delta transform
python train_fast_tokenizer.py \
--repo_id "lerobot/aloha_sim_insertion_human" \
--action_horizon 10 \
--encoded_dims "0:14" \
--delta_dims "0,1,2,3,4,5,6,7,8,9,10,11,12,13" \
--state_key "observation.state" \
--vocab_size 1024
```
## What is FAST?
FAST is a tokenizer for robotic action sequences that:
1. Applies DCT (Discrete Cosine Transform) to action chunks
2. Quantizes DCT coefficients
3. Uses BPE (Byte-Pair Encoding) to compress the quantized sequence
4. Achieves high compression ratios (e.g., 10-20x) while maintaining accuracy
This enables efficient storage and processing of long action sequences in vision-language-action models.
## Requirements
- Python 3.10+
- LeRobot dataset (either local or from HuggingFace Hub)
- transformers (for AutoProcessor)
- numpy
- torch
- tyro
## Workflow
```
LeRobotDataset → Extract Episodes → Apply Delta Transform
Select Dimensions → Normalize (q01, q99) → Create Chunks
Train FAST Tokenizer → Compute Stats → Save
```
## Parameters Guide
### Essential Parameters
- **`repo_id`**: HuggingFace dataset repository ID
- Example: `"lerobot/aloha_sim_insertion_human"`
- **`action_horizon`**: Length of action sequences to tokenize
- Typical: 10-16 steps
- **`encoded_dims`**: Which action dimensions to encode
- Format: `"start:end,start:end"`
- Example: `"0:7"` = dimensions 0-6
- Example: `"0:3,7:10"` = dimensions 0-2 and 7-9
### Optional Parameters
- **`delta_dims`**: Apply delta transform (action - state) to these dimensions
- Format: `"0,1,2,3,4,5"`
- Use for position-based actions
- **`state_key`**: Dataset key containing state observations
- Default: `"observation.state"`
- **`vocab_size`**: BPE vocabulary size
- Default: 1024
- Larger = better compression but more memory
- **`scale`**: DCT quantization scale
- Default: 10.0
- Smaller = finer quantization, larger = coarser
- **`sample_fraction`**: Fraction of action chunks to use per episode
- Default: 0.1 (10%)
- Increase for small datasets, decrease for large datasets
## Output
The script creates a directory (default: `./fast_tokenizer_{repo_id}`) containing:
1. **Tokenizer files**: Can be loaded with `AutoProcessor.from_pretrained()`
2. **`metadata.json`**: Contains:
- Training configuration
- Compression statistics
- Dataset information
## Example Output
```
Loading dataset: lerobot/aloha_sim_insertion_human
Dataset loaded: 50 episodes, 5000 frames
Encoding 14 dimensions: 0:14
Delta dimensions: [0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13]
Action horizon: 10
Processing 50 episodes...
Collected 4500 action chunks
Extracted 14 encoded dimensions
Before normalization - overall stats:
Min: -2.3451, Max: 3.1234, Mean: 0.0234, Std: 0.8765
Applied quantile normalization [q01, q99] → [-1, 1]
After normalization - overall stats:
Min: -1.0000, Max: 1.0000, Mean: 0.0156, Std: 0.4321
Training FAST tokenizer on 4500 action chunks...
Action chunk shape: (4500, 10, 14)
Vocab size: 1024
DCT scale: 10.0
✓ Tokenizer training complete!
Compression Statistics:
Average compression ratio: 14.23x
Mean token length: 9.8
P99 token length: 15
Min token length: 6
Max token length: 18
✅ Saved FAST tokenizer to ./fast_tokenizer_lerobot_aloha_sim_insertion_human
```
## Using the Trained Tokenizer
```python
from transformers import AutoProcessor
# Load tokenizer
tokenizer = AutoProcessor.from_pretrained(
"./fast_tokenizer_lerobot_aloha_sim_insertion_human",
trust_remote_code=True
)
# Encode action chunk [horizon, action_dim]
action_chunk = np.random.randn(10, 14) # Example
tokens = tokenizer(action_chunk[None])[0] # Returns token IDs
# Decode tokens back to actions
reconstructed = tokenizer.decode(tokens)
```
## Tips
1. **Start Small**: Use `--max_episodes 10` for initial testing
2. **Check Dimensions**: Verify encoded dimensions match your robot's action space
3. **Delta Transform**: Use for position-based actions, not velocity-based
4. **Normalization**: Ensure dataset has proper statistics computed
5. **Compression Ratio**: Aim for 10-20x for good balance of compression and accuracy
## Troubleshooting
**Issue**: "No normalization stats found"
- **Solution**: Compute dataset statistics first, or use raw actions
**Issue**: "Episode too short for action horizon"
- **Solution**: Reduce `--action_horizon` or filter short episodes
**Issue**: "State key not found"
- **Solution**: Check dataset features and use correct `--state_key`
**Issue**: Memory error with large datasets
- **Solution**: Reduce `--sample_fraction` or `--max_episodes`
## Citation
If you use FAST in your research, please cite:
```bibtex
@article{black2023fast,
title={FAST: Factorized Action Sequence Tokenizer for Vision-Language-Action Models},
author={Black, Kevin and others},
journal={arXiv preprint},
year={2023}
}
```

7
src/lerobot/policies/pi05/configuration_pi05.py
View File

@@ -37,6 +37,9 @@ class PI05Config(PreTrainedConfig):
# Shorter state and action vectors will be padded to these dimensions
max_state_dim: int = 32
max_action_dim: int = 32
max_action_tokens: int = 32
fast_vocab_size: int = 2048
# Flow matching parameters: see openpi `PI0Pytorch`
num_inference_steps: int = 10
@@ -60,8 +63,8 @@ class PI05Config(PreTrainedConfig):
normalization_mapping: dict[str, NormalizationMode] = field(
default_factory=lambda: {
"VISUAL": NormalizationMode.IDENTITY,
"STATE": NormalizationMode.QUANTILES, # Pi0.5 uses quantiles for state
"ACTION": NormalizationMode.QUANTILES, # Pi0.5 uses quantiles for action
"STATE": NormalizationMode.MEAN_STD, # Pi0.5 uses quantiles for state
"ACTION": NormalizationMode.MEAN_STD, # Pi0.5 uses quantiles for action
}
)

21
src/lerobot/policies/pi05/finetune_pi0.sh Normal file
View File

@@ -0,0 +1,21 @@
lerobot-train \
--dataset.repo_id=lerobot \
--dataset.root=/fsx/jade_choghari/outputs/collect-data-pgen \
--output_dir=/fsx/jade_choghari/outputs/pi0test1 \
--job_name=pi0_training \
--policy.repo_id=jade_choghari/pi0-base \
--policy.path=/fsx/jade_choghari/outputs/pi0_fast_fruit1/checkpoints/last/pretrained_model \
--policy.dtype=bfloat16 \
--steps=3000 \
--save_freq=1000 \
--rename_map='{
"observation.images.base": "observation.images.base_0_rgb",
"observation.images.left_wrist": "observation.images.left_wrist_0_rgb",
"observation.images.right_wrist": "observation.images.right_wrist_0_rgb",
}' \
--batch_size=4 \
--policy.device=cuda \
# --wandb.enable=true \
# --wandb.disable_artifact=true \
# --wandb.project=pi05hi-training \

695
src/lerobot/policies/pi05/modeling_pi05.py
View File

@@ -48,6 +48,10 @@ from lerobot.utils.constants import (
ACTION,
OBS_LANGUAGE_ATTENTION_MASK,
OBS_LANGUAGE_TOKENS,
OBS_LANGUAGE_HIGH_LEVEL_TASK_TOKENS,
OBS_LANGUAGE_HIGH_LEVEL_TASK_ATTENTION_MASK,
OBS_LANGUAGE_SUBTASK_ONLY_TOKENS,
OBS_LANGUAGE_SUBTASK_ONLY_ATTENTION_MASK,
OPENPI_ATTENTION_MASK_VALUE,
)
@@ -429,6 +433,8 @@ class PaliGemmaWithExpertModel(
adarms_cond=adarms_cond[0] if adarms_cond is not None else None,
)
prefix_past_key_values = prefix_output.past_key_values
# prefix_output to be used for the language head
# shape: [batch_size, seq_len, hidden_size] with hidden_size = 2048
prefix_output = prefix_output.last_hidden_state
suffix_output = None
elif inputs_embeds[0] is None:
@@ -531,6 +537,18 @@ class PI05Pytorch(nn.Module): # see openpi `PI0Pytorch`
self.time_mlp_in = nn.Linear(action_expert_config.width, action_expert_config.width)
self.time_mlp_out = nn.Linear(action_expert_config.width, action_expert_config.width)
# FAST action token embedding and prediction head
self.fast_action_embedding = nn.Embedding(config.fast_vocab_size, paligemma_config.width)
self.fast_action_lm_head = nn.Linear(paligemma_config.width, config.fast_vocab_size)
# Apply dtype conversion to FAST layers to match model precision
if config.dtype == "bfloat16":
self.fast_action_embedding = self.fast_action_embedding.to(dtype=torch.bfloat16)
self.fast_action_lm_head = self.fast_action_lm_head.to(dtype=torch.bfloat16)
elif config.dtype == "float32":
self.fast_action_embedding = self.fast_action_embedding.to(dtype=torch.float32)
self.fast_action_lm_head = self.fast_action_lm_head.to(dtype=torch.float32)
# Initialize gradient checkpointing flag
self.gradient_checkpointing_enabled = False
@@ -538,6 +556,8 @@ class PI05Pytorch(nn.Module): # see openpi `PI0Pytorch`
if config.compile_model:
torch.set_float32_matmul_precision("high")
self.sample_actions = torch.compile(self.sample_actions, mode=config.compile_mode)
# Also compile the main forward pass used during training
self.forward = torch.compile(self.forward, mode=config.compile_mode)
msg = """An incorrect transformer version is used, please create an issue on https://github.com/huggingface/lerobot/issues"""
@@ -576,10 +596,201 @@ class PI05Pytorch(nn.Module): # see openpi `PI0Pytorch`
)
return func(*args, **kwargs)
def _prepare_attention_masks_4d(self, att_2d_masks):
def _prepare_attention_masks_4d(self, att_2d_masks, dtype=None):
"""Helper method to prepare 4D attention masks for transformer."""
att_2d_masks_4d = att_2d_masks[:, None, :, :]
return torch.where(att_2d_masks_4d, 0.0, OPENPI_ATTENTION_MASK_VALUE)
result = torch.where(att_2d_masks_4d, 0.0, OPENPI_ATTENTION_MASK_VALUE)
if dtype is not None:
result = result.to(dtype=dtype)
return result
def _create_custom_attention_mask(self, att_mask_segments, pad_masks, bsize):
"""Create custom 2D attention mask for the new attention pattern.
Attention rules:
- Images + Language: bidirectional among themselves, don't attend to subtask or FAST
- Subtask: attend to images + language, causal among themselves, don't attend to FAST
- FAST: attend to images + language + subtask, causal among themselves
Args:
att_mask_segments: List of (type, length) tuples
pad_masks: Padding masks [B, total_seq_len]
bsize: Batch size
Returns:
att_2d_masks: 2D attention mask [B, total_seq_len, total_seq_len]
"""
total_len = sum(length for _, length in att_mask_segments)
device = pad_masks.device
# Initialize attention mask as False (cannot attend)
att_2d_masks = torch.zeros(bsize, total_len, total_len, dtype=torch.bool, device=device)
# Track positions for each segment
positions = []
current_pos = 0
for seg_type, seg_len in att_mask_segments:
positions.append((seg_type, current_pos, current_pos + seg_len))
current_pos += seg_len
# Apply attention rules
for i, (query_type, query_start, query_end) in enumerate(positions):
for j, (key_type, key_start, key_end) in enumerate(positions):
# Images and Language can attend to each other bidirectionally
if query_type in ['image', 'language'] and key_type in ['image', 'language']:
att_2d_masks[:, query_start:query_end, key_start:key_end] = True
# Subtask tokens attend to images + language
elif query_type == 'subtask' and key_type in ['image', 'language']:
att_2d_masks[:, query_start:query_end, key_start:key_end] = True
# Subtask tokens attend causally to themselves
elif query_type == 'subtask' and key_type == 'subtask':
# Create causal mask for subtask tokens
subtask_len = query_end - query_start
causal_mask = torch.tril(torch.ones(subtask_len, subtask_len, dtype=torch.bool, device=device))
att_2d_masks[:, query_start:query_end, key_start:key_end] = causal_mask[None, :, :]
# FAST tokens attend to images + language + subtask
elif query_type == 'fast' and key_type in ['image', 'language', 'subtask']:
att_2d_masks[:, query_start:query_end, key_start:key_end] = True
# FAST tokens attend causally to themselves
elif query_type == 'fast' and key_type == 'fast':
fast_len = query_end - query_start
causal_mask = torch.tril(torch.ones(fast_len, fast_len, dtype=torch.bool, device=device))
att_2d_masks[:, query_start:query_end, key_start:key_end] = causal_mask[None, :, :]
# Apply padding masks
pad_2d_masks = pad_masks[:, None, :] * pad_masks[:, :, None]
att_2d_masks = att_2d_masks & pad_2d_masks
return att_2d_masks
def visualize_attention_mask(
self,
att_mask_segments,
att_2d_masks,
save_path,
batch_idx=0,
dpi=150,
max_display_tokens=None
):
"""Visualize the attention mask with labeled segments.
Args:
att_mask_segments: List of (type, length) tuples defining the segments
att_2d_masks: 2D attention mask tensor [B, total_seq_len, total_seq_len]
save_path: Path where to save the visualization image
batch_idx: Which batch item to visualize (default: 0)
dpi: DPI for the saved image (default: 150)
max_display_tokens: Maximum number of tokens to display (for very long sequences)
"""
try:
import matplotlib.pyplot as plt
import matplotlib.patches as mpatches
from matplotlib.colors import LinearSegmentedColormap
except ImportError:
logging.warning("matplotlib not available, skipping attention mask visualization")
return
# Extract the mask for the specified batch
mask = att_2d_masks[batch_idx].cpu().float().numpy()
# If sequence is too long, downsample for visualization
if max_display_tokens is not None and mask.shape[0] > max_display_tokens:
# Simple downsampling by taking every Nth token
step = mask.shape[0] // max_display_tokens
mask = mask[::step, ::step]
# Adjust segments accordingly
att_mask_segments = [(seg_type, max(1, seg_len // step)) for seg_type, seg_len in att_mask_segments]
# Calculate positions for each segment
positions = []
current_pos = 0
for seg_type, seg_len in att_mask_segments:
positions.append((seg_type, current_pos, current_pos + seg_len))
current_pos += seg_len
# Create figure
fig, ax = plt.subplots(figsize=(12, 10))
# Create custom colormap: white for False (no attention), blue for True (attention)
colors = ['white', '#2E86AB']
n_bins = 2
cmap = LinearSegmentedColormap.from_list('attention', colors, N=n_bins)
# Display the mask
im = ax.imshow(mask, cmap=cmap, aspect='auto', interpolation='nearest', vmin=0, vmax=1)
# Add colorbar
cbar = plt.colorbar(im, ax=ax, fraction=0.046, pad=0.04)
cbar.set_label('Attention Enabled', rotation=270, labelpad=20)
cbar.set_ticks([0.25, 0.75])
cbar.set_ticklabels(['No', 'Yes'])
# Define colors for each segment type
segment_colors = {
'image': '#A23B72',
'language': '#F18F01',
'subtask': '#C73E1D',
'fast': '#6A994E'
}
# Draw segment boundaries and labels
for seg_type, start, end in positions:
color = segment_colors.get(seg_type, '#666666')
# Draw vertical lines for columns (keys)
ax.axvline(x=start - 0.5, color=color, linewidth=2, alpha=0.7)
ax.axvline(x=end - 0.5, color=color, linewidth=2, alpha=0.7)
# Draw horizontal lines for rows (queries)
ax.axhline(y=start - 0.5, color=color, linewidth=2, alpha=0.7)
ax.axhline(y=end - 0.5, color=color, linewidth=2, alpha=0.7)
# Add labels at the top
mid_pos = (start + end) / 2
ax.text(mid_pos, -mask.shape[0] * 0.02, f"{seg_type.upper()}\n({end - start})",
ha='center', va='top', fontsize=10, fontweight='bold', color=color)
# Add labels on the left
ax.text(-mask.shape[1] * 0.02, mid_pos, f"{seg_type.upper()}\n({end - start})",
ha='right', va='center', fontsize=10, fontweight='bold', color=color, rotation=0)
# Set axis labels
ax.set_xlabel('Key Position (tokens being attended to)', fontsize=12, fontweight='bold')
ax.set_ylabel('Query Position (tokens attending)', fontsize=12, fontweight='bold')
ax.set_title('Attention Mask Pattern\n(White = No Attention, Blue = Attention Allowed)',
fontsize=14, fontweight='bold', pad=20)
# Create legend for segment types
legend_patches = []
attention_rules = {
'image': 'Bidirectional with lang',
'language': 'Bidirectional with images',
'subtask': 'Attends to img+lang, causal self',
'fast': 'Attends to all, causal self'
}
for seg_type, color in segment_colors.items():
if any(seg[0] == seg_type for seg in att_mask_segments):
rule = attention_rules.get(seg_type, '')
legend_patches.append(mpatches.Patch(color=color, label=f'{seg_type.upper()}: {rule}'))
ax.legend(handles=legend_patches, loc='upper right', bbox_to_anchor=(1.15, 1.0),
framealpha=0.9, fontsize=9)
# Adjust layout and save
plt.tight_layout()
# Ensure the directory exists
save_path = Path(save_path)
save_path.parent.mkdir(parents=True, exist_ok=True)
plt.savefig(save_path, dpi=dpi, bbox_inches='tight')
plt.close()
logging.info(f"Attention mask visualization saved to: {save_path}")
def sample_noise(self, shape, device):
return torch.normal(
@@ -598,12 +809,41 @@ class PI05Pytorch(nn.Module): # see openpi `PI0Pytorch`
return time.to(dtype=torch.float32, device=device)
def embed_prefix(
self, images, img_masks, tokens, masks
) -> tuple[torch.Tensor, torch.Tensor, torch.Tensor]:
"""Embed images with SigLIP and language tokens with embedding layer."""
self,
images,
img_masks,
tokens,
subtask_tokens,
masks,
subtask_masks,
fast_action_tokens=None,
fast_action_masks=None,
) -> tuple[torch.Tensor, torch.Tensor, torch.Tensor, int, int, int]:
"""Embed images with SigLIP, tokens, and optionally subtask tokens with embedding layer.
Args:
images: List of image tensors
img_masks: List of image masks
tokens: Language instruction tokens
subtask_tokens: Subtask tokens to predict (can be None for inference)
masks: Attention masks for tokens
fast_action_tokens: FAST action tokens for auxiliary prediction (can be None) - discrete token IDs
fast_action_masks: Padding masks for FAST action tokens (can be None)
Returns:
embs: Concatenated embeddings [images, tokens, (subtask_tokens if provided), (fast_action_tokens if provided)]
pad_masks: Padding masks
att_masks: Custom 2D attention mask implementing the required pattern
total_T_images: Total number of image tokens
num_subtask_embs: Number of subtask token embeddings
num_fast_embs: Number of FAST action token embeddings
"""
embs = []
pad_masks = []
att_masks = []
att_mask_segments = [] # Store info about each segment for custom mask creation
total_T_images = 0
num_subtask_embs = 0
num_fast_embs = 0
# Process images
for img, img_mask in zip(images, img_masks, strict=True):
@@ -616,9 +856,10 @@ class PI05Pytorch(nn.Module): # see openpi `PI0Pytorch`
embs.append(img_emb)
pad_masks.append(img_mask[:, None].expand(bsize, num_img_embs))
att_masks += [0] * num_img_embs
att_mask_segments.append(('image', num_img_embs))
total_T_images += num_img_embs
# Process language tokens
# Process language instruction tokens
def lang_embed_func(tokens):
lang_emb = self.paligemma_with_expert.embed_language_tokens(tokens)
lang_emb_dim = lang_emb.shape[-1]
@@ -629,16 +870,65 @@ class PI05Pytorch(nn.Module): # see openpi `PI0Pytorch`
pad_masks.append(masks)
num_lang_embs = lang_emb.shape[1]
att_masks += [0] * num_lang_embs
att_mask_segments.append(('language', num_lang_embs))
# Process subtask tokens if provided (these are predicted, so use causal masking)
if subtask_tokens is not None:
def subtask_embed_func(subtask_tokens):
subtask_emb = self.paligemma_with_expert.embed_language_tokens(subtask_tokens)
subtask_emb_dim = subtask_emb.shape[-1]
return subtask_emb * math.sqrt(subtask_emb_dim)
subtask_emb = self._apply_checkpoint(subtask_embed_func, subtask_tokens)
embs.append(subtask_emb)
# Create subtask pad masks (non-zero tokens are valid)
pad_masks.append(subtask_masks)
num_subtask_embs = subtask_emb.shape[1]
att_mask_segments.append(('subtask', num_subtask_embs))
# Process FAST action tokens if provided (these are discrete token IDs)
if fast_action_tokens is not None:
def fast_action_embed_func(fast_action_tokens):
fast_emb = self.fast_action_embedding(fast_action_tokens)
fast_emb_dim = fast_emb.shape[-1]
return fast_emb * math.sqrt(fast_emb_dim)
fast_action_emb = self._apply_checkpoint(fast_action_embed_func, fast_action_tokens)
embs.append(fast_action_emb)
# Use provided mask or create default (all valid)
if fast_action_masks is not None:
fast_pad_mask = fast_action_masks
else:
bsize = fast_action_tokens.shape[0]
num_fast_embs = fast_action_tokens.shape[1]
fast_pad_mask = torch.ones(bsize, num_fast_embs, dtype=torch.bool, device=fast_action_tokens.device)
num_fast_embs = fast_action_tokens.shape[1]
pad_masks.append(fast_pad_mask)
att_mask_segments.append(('fast', num_fast_embs))
embs = torch.cat(embs, dim=1)
pad_masks = torch.cat(pad_masks, dim=1)
att_masks = torch.tensor(att_masks, dtype=torch.bool, device=pad_masks.device)
bsize = pad_masks.shape[0]
att_masks = att_masks[None, :].expand(bsize, len(att_masks))
# Create custom 2D attention mask
# Attention rules:
# - Images + Language: bidirectional among themselves, don't attend to subtask or FAST
# - Subtask: attend to images + language, causal among themselves, don't attend to FAST
# - FAST: attend to images + language + subtask, causal among themselves
att_masks = self._create_custom_attention_mask(att_mask_segments, pad_masks, bsize)
return embs, pad_masks, att_masks
# # Optionally visualize the attention mask
# self.visualize_attention_mask(
# att_mask_segments=att_mask_segments,
# att_2d_masks=att_masks,
# save_path="/admin/home/jade_choghari/lerobot/src/lerobot/policies/pi05/attention_mask_visualization.png",
# batch_idx=0,
# max_display_tokens=512 # Limit display for very long sequences
# )
return embs, pad_masks, att_masks, total_T_images, num_subtask_embs, num_fast_embs
def embed_suffix(self, noisy_actions, timestep):
"""Embed noisy_actions, timestep to prepare for Expert Gemma processing."""
@@ -687,8 +977,23 @@ class PI05Pytorch(nn.Module): # see openpi `PI0Pytorch`
return embs, pad_masks, att_masks, adarms_cond
def forward(self, images, img_masks, tokens, masks, actions, noise=None, time=None) -> Tensor:
"""Do a full training forward pass and compute the loss."""
# loss_dict = self.model.forward(images, img_masks, high_level_task, tokens, masks, subtask_tokens, subtask_masks, actions, fast_action_tokens, fast_action_masks)
def forward(self, images, img_masks, high_level_task, high_level_task_masks, subtask_tokens, subtask_masks, actions, fast_action_tokens=None, fast_action_masks=None, noise=None, time=None) -> Tensor:
"""Do a full training forward pass and compute the loss.
Args:
images: List of image tensors
img_masks: List of image masks
high_level_task: Instruction tokens WITHOUT subtask (e.g., "High level task: X; State: Y; Subtask:")
high_level_task_masks: Attention masks for high_level_task
subtask_tokens: Subtask tokens to predict (e.g., tokens for "pick up the cup")
subtask_masks: Attention masks for subtask_tokens
actions: Ground truth actions [B, chunk_size, action_dim]
fast_action_tokens: Discrete action token IDs [B, max_action_tokens]
fast_action_masks: Padding masks for fast action tokens [B, max_action_tokens]
noise: Optional noise for flow matching
time: Optional time for flow matching
"""
if noise is None:
noise = self.sample_noise(actions.shape, actions.device)
@@ -699,23 +1004,183 @@ class PI05Pytorch(nn.Module): # see openpi `PI0Pytorch`
x_t = time_expanded * noise + (1 - time_expanded) * actions
u_t = noise - actions
prefix_embs, prefix_pad_masks, prefix_att_masks = self.embed_prefix(images, img_masks, tokens, masks)
# Initialize FAST loss to 0 (will be computed only if FAST tokens are provided)
fast_loss = torch.tensor(0.0, device=actions.device, dtype=actions.dtype)
# ========== PASS 1: Prefix with FAST tokens for subtask + FAST prediction ==========
# Only run this pass if FAST action tokens are provided
if fast_action_tokens is not None and fast_action_masks is not None:
# Embed prefix (images + high_level_task + subtask_tokens + FAST tokens)
# FAST tokens are provided as discrete token IDs
prefix_with_fast_embs, prefix_with_fast_pad_masks, prefix_with_fast_att_masks, total_T_images, num_subtask_embs, num_fast_embs = self.embed_prefix(
images, img_masks, high_level_task, subtask_tokens, high_level_task_masks, subtask_masks,
fast_action_tokens=fast_action_tokens, fast_action_masks=fast_action_masks
)
# Convert embeddings to bfloat16 if needed for the model
if (
self.paligemma_with_expert.paligemma.language_model.layers[0].self_attn.q_proj.weight.dtype
== torch.bfloat16
):
prefix_with_fast_embs = prefix_with_fast_embs.to(dtype=torch.bfloat16)
# Prepare attention masks for prefix pass with FAST tokens
position_ids_prefix_with_fast = torch.cumsum(prefix_with_fast_pad_masks, dim=1) - 1
att_2d_prefix_with_fast_4d = self._prepare_attention_masks_4d(prefix_with_fast_att_masks, dtype=prefix_with_fast_embs.dtype)
# Forward pass through paligemma for subtask + FAST prediction
(prefix_with_fast_out, _), _ = self.paligemma_with_expert.forward(
attention_mask=att_2d_prefix_with_fast_4d,
position_ids=position_ids_prefix_with_fast,
past_key_values=None,
inputs_embeds=[prefix_with_fast_embs, None], # SUFFIX = None
use_cache=False,
adarms_cond=[None, None],
)
# LM HEAD → SUBTASK LOGITS
lm_head = self.paligemma_with_expert.paligemma.lm_head
logits = lm_head(prefix_with_fast_out) # (B, T_prefix_with_fast, vocab)
# Extract logits for subtask token prediction
T_high_level_task = high_level_task.size(1)
T_subtask = subtask_tokens.size(1)
start_index = total_T_images + T_high_level_task
end_index = start_index + T_subtask
logits_subtask = logits[:, start_index-1:end_index-1, :] # (B, T_subtask, vocab)
targets = subtask_tokens # (B, T_subtask)
# Compute cross-entropy loss for subtask
loss_fct = torch.nn.CrossEntropyLoss(reduction='none')
logits_flat = logits_subtask.reshape(-1, logits_subtask.size(-1))
targets_flat = targets.reshape(-1)
loss_per_token = loss_fct(logits_flat, targets_flat)
loss_per_token = loss_per_token.reshape(targets.shape)
masked_loss = loss_per_token * subtask_masks.float()
subtask_loss = masked_loss.sum() / subtask_masks.sum().clamp(min=1)
# Extract outputs for FAST action token prediction and compute auxiliary loss
# FAST outputs start after subtask tokens
# Similar to subtask, we use autoregressive prediction where position i predicts token i+1
fast_start_index = end_index
fast_end_index = fast_start_index + num_fast_embs
# Get logits for FAST action tokens using the FAST LM head
fast_logits = self.fast_action_lm_head(prefix_with_fast_out) # (B, T_prefix_with_fast, fast_vocab_size)
# Extract logits for FAST token prediction (autoregressive: position i predicts token i+1)
# - Position (fast_start_index-1) predicts fast_action_tokens[0]
# - Position (fast_start_index) predicts fast_action_tokens[1], etc.
fast_logits_for_pred = fast_logits[:, fast_start_index-1:fast_end_index-1, :] # (B, max_action_tokens, fast_vocab_size)
# Compute cross-entropy loss for FAST action tokens
fast_targets = fast_action_tokens # (B, max_action_tokens)
loss_fct_fast = torch.nn.CrossEntropyLoss(reduction='none')
fast_logits_flat = fast_logits_for_pred.reshape(-1, fast_logits_for_pred.size(-1)) # (B*max_action_tokens, fast_vocab_size)
fast_targets_flat = fast_targets.reshape(-1) # (B*max_action_tokens)
fast_loss_per_token = loss_fct_fast(fast_logits_flat, fast_targets_flat) # (B*max_action_tokens)
fast_loss_per_token = fast_loss_per_token.reshape(fast_targets.shape) # (B, max_action_tokens)
# Apply mask and compute mean loss over valid tokens
masked_fast_loss = fast_loss_per_token * fast_action_masks.float()
fast_loss = masked_fast_loss.sum() / fast_action_masks.sum().clamp(min=1)
else:
# If no FAST tokens provided, compute subtask loss without FAST tokens
# This is the fallback for backward compatibility
prefix_embs_for_subtask, prefix_pad_masks_for_subtask, prefix_att_masks_for_subtask, total_T_images, _, _ = self.embed_prefix(
images, img_masks, high_level_task, subtask_tokens, high_level_task_masks, subtask_masks,
fast_action_tokens=None, fast_action_masks=None
)
# Convert embeddings to bfloat16 if needed for the model
if (
self.paligemma_with_expert.paligemma.language_model.layers[0].self_attn.q_proj.weight.dtype
== torch.bfloat16
):
prefix_embs_for_subtask = prefix_embs_for_subtask.to(dtype=torch.bfloat16)
position_ids_prefix = torch.cumsum(prefix_pad_masks_for_subtask, dim=1) - 1
att_2d_prefix_4d = self._prepare_attention_masks_4d(prefix_att_masks_for_subtask, dtype=prefix_embs_for_subtask.dtype)
(prefix_out, _), _ = self.paligemma_with_expert.forward(
attention_mask=att_2d_prefix_4d,
position_ids=position_ids_prefix,
past_key_values=None,
inputs_embeds=[prefix_embs_for_subtask, None],
use_cache=False,
adarms_cond=[None, None],
)
lm_head = self.paligemma_with_expert.paligemma.lm_head
logits = lm_head(prefix_out)
T_high_level_task = high_level_task.size(1)
T_subtask = subtask_tokens.size(1)
start_index = total_T_images + T_high_level_task
end_index = start_index + T_subtask
logits_subtask = logits[:, start_index-1:end_index-1, :]
targets = subtask_tokens
loss_fct = torch.nn.CrossEntropyLoss(reduction='none')
logits_flat = logits_subtask.reshape(-1, logits_subtask.size(-1))
targets_flat = targets.reshape(-1)
loss_per_token = loss_fct(logits_flat, targets_flat)
loss_per_token = loss_per_token.reshape(targets.shape)
masked_loss = loss_per_token * subtask_masks.float()
subtask_loss = masked_loss.sum() / subtask_masks.sum().clamp(min=1)
# ========== PASS 2: Full forward WITHOUT FAST tokens for flow matching ==========
# Embed prefix WITHOUT FAST tokens (images + high_level_task + subtask_tokens)
prefix_embs_no_fast, prefix_pad_masks_no_fast, prefix_att_masks_no_fast, _, _, _ = self.embed_prefix(
images, img_masks, high_level_task, subtask_tokens, high_level_task_masks, subtask_masks,
fast_action_tokens=None, fast_action_masks=None
)
suffix_embs, suffix_pad_masks, suffix_att_masks, adarms_cond = self.embed_suffix(x_t, time)
# Convert embeddings to bfloat16 if needed for the model
if (
self.paligemma_with_expert.paligemma.language_model.layers[0].self_attn.q_proj.weight.dtype
== torch.bfloat16
):
suffix_embs = suffix_embs.to(dtype=torch.bfloat16)
prefix_embs = prefix_embs.to(dtype=torch.bfloat16)
prefix_embs_no_fast = prefix_embs_no_fast.to(dtype=torch.bfloat16)
pad_masks = torch.cat([prefix_pad_masks, suffix_pad_masks], dim=1)
att_masks = torch.cat([prefix_att_masks, suffix_att_masks], dim=1)
# For the flow matching pass, we need custom attention where:
# - prefix follows the custom pattern (images+lang bidirectional, subtask causal, no cross-attention)
# - suffix attends to all prefix + causal to itself
# We'll construct this by extending prefix_att_masks_no_fast to include suffix
# prefix_att_masks_no_fast is already a 2D boolean mask [B, prefix_len, prefix_len]
# We need to extend it to [B, prefix_len + suffix_len, prefix_len + suffix_len]
bsize = prefix_pad_masks_no_fast.shape[0]
prefix_len = prefix_pad_masks_no_fast.shape[1]
suffix_len = suffix_pad_masks.shape[1]
total_len = prefix_len + suffix_len
device = prefix_pad_masks_no_fast.device
# Create full attention mask
full_att_2d_masks = torch.zeros(bsize, total_len, total_len, dtype=torch.bool, device=device)
# Copy prefix attention pattern
full_att_2d_masks[:, :prefix_len, :prefix_len] = prefix_att_masks_no_fast
# Suffix attends to all prefix
full_att_2d_masks[:, prefix_len:, :prefix_len] = True
# Suffix has causal attention among itself
suffix_causal_mask = torch.tril(torch.ones(suffix_len, suffix_len, dtype=torch.bool, device=device))
full_att_2d_masks[:, prefix_len:, prefix_len:] = suffix_causal_mask[None, :, :]
# Apply padding masks
pad_masks = torch.cat([prefix_pad_masks_no_fast, suffix_pad_masks], dim=1)
pad_2d_masks = pad_masks[:, None, :] * pad_masks[:, :, None]
full_att_2d_masks = full_att_2d_masks & pad_2d_masks
att_2d_masks = make_att_2d_masks(pad_masks, att_masks)
position_ids = torch.cumsum(pad_masks, dim=1) - 1
att_2d_masks_4d = self._prepare_attention_masks_4d(att_2d_masks)
att_2d_masks_4d = self._prepare_attention_masks_4d(full_att_2d_masks, dtype=prefix_embs_no_fast.dtype)
def forward_func(prefix_embs, suffix_embs, att_2d_masks_4d, position_ids, adarms_cond):
(_, suffix_out), _ = self.paligemma_with_expert.forward(
@@ -729,7 +1194,7 @@ class PI05Pytorch(nn.Module): # see openpi `PI0Pytorch`
return suffix_out
suffix_out = self._apply_checkpoint(
forward_func, prefix_embs, suffix_embs, att_2d_masks_4d, position_ids, adarms_cond
forward_func, prefix_embs_no_fast, suffix_embs, att_2d_masks_4d, position_ids, adarms_cond
)
suffix_out = suffix_out[:, -self.config.chunk_size :]
@@ -740,7 +1205,87 @@ class PI05Pytorch(nn.Module): # see openpi `PI0Pytorch`
v_t = self._apply_checkpoint(action_out_proj_func, suffix_out)
return F.mse_loss(u_t, v_t, reduction="none")
fm_loss = F.mse_loss(u_t, v_t, reduction="none")
return {
"flow_loss": fm_loss,
"subtask_loss": subtask_loss,
"fast_loss": fast_loss,
"loss": fm_loss.mean() + 0.1 * subtask_loss + 0.05 * fast_loss, # ref: b1k winner
}
@torch.no_grad()
def _generate_subtask_tokens(
self, images, img_masks, tokens, masks, tokenizer, max_length, device
):
bsize = tokens.shape[0]
lm_head = self.paligemma_with_expert.paligemma.lm_head
prefix_embs, prefix_pad_masks, prefix_att_masks, total_T_images, _, _ = self.embed_prefix(
images, img_masks, tokens, subtask_tokens=None, masks=masks, subtask_masks=None,
fast_action_tokens=None, fast_action_masks=None
)
generated_tokens = torch.zeros((bsize, max_length), dtype=torch.long, device=device)
# tracking mask: False = still generating, True = finished
finished = torch.zeros(bsize, dtype=torch.bool, device=device)
for t in range(max_length):
position_ids_prefix = torch.cumsum(prefix_pad_masks, dim=1) - 1
att_2d_prefix_4d = self._prepare_attention_masks_4d(prefix_att_masks, dtype=prefix_embs.dtype)
(prefix_out, _), _ = self.paligemma_with_expert.forward(
attention_mask=att_2d_prefix_4d,
position_ids=position_ids_prefix,
inputs_embeds=[prefix_embs, None],
# ...
)
logits = lm_head(prefix_out)
next_token_logits = logits[:, -1, :]
next_token = torch.argmax(next_token_logits, dim=-1) # (B,)
# 1. if a row was already finished, force the next token to be PAD (0)
next_token = torch.where(finished, torch.tensor(0, device=device), next_token)
# 2. store the token
generated_tokens[:, t] = next_token
# 3. update the finished mask
if tokenizer.eos_token_id is not None:
finished |= (next_token == tokenizer.eos_token_id)
# 4. break only if everyone is finished
if finished.all():
break
next_token_unsqueezed = next_token.unsqueeze(1)
def next_token_embed_func(next_token_unsqueezed):
next_emb = self.paligemma_with_expert.embed_language_tokens(next_token_unsqueezed)
return next_emb * math.sqrt(next_emb.shape[-1])
next_emb = self._apply_checkpoint(next_token_embed_func, next_token_unsqueezed)
# update embeddings
prefix_embs = torch.cat([prefix_embs, next_emb], dim=1)
# update padding masks
prefix_pad_masks = torch.cat([
prefix_pad_masks,
torch.ones((bsize, 1), dtype=torch.bool, device=device)
], dim=1)
# update attention masks
old_seq_len = prefix_att_masks.shape[1]
new_seq_len = old_seq_len + 1
new_att_masks = torch.zeros((bsize, new_seq_len, new_seq_len), dtype=torch.bool, device=device)
new_att_masks[:, :old_seq_len, :old_seq_len] = prefix_att_masks
new_att_masks[:, -1, :] = prefix_pad_masks
prefix_att_masks = new_att_masks
return generated_tokens
@torch.no_grad() # see openpi `sample_actions` (slightly adapted)
def sample_actions(
@@ -751,6 +1296,8 @@ class PI05Pytorch(nn.Module): # see openpi `PI0Pytorch`
masks,
noise=None,
num_steps=None,
tokenizer=None,
max_subtask_tokens=50,
**kwargs: Unpack[ActionSelectKwargs],
) -> Tensor:
"""Do a full inference forward and compute the action."""
@@ -769,11 +1316,41 @@ class PI05Pytorch(nn.Module): # see openpi `PI0Pytorch`
) # Use config max_action_dim for internal processing
noise = self.sample_noise(actions_shape, device)
prefix_embs, prefix_pad_masks, prefix_att_masks = self.embed_prefix(images, img_masks, tokens, masks)
prefix_att_2d_masks = make_att_2d_masks(prefix_pad_masks, prefix_att_masks)
# Generate subtask tokens autoregressively during inference
generated_subtask_tokens = None
if tokenizer is not None:
generated_subtask_tokens = self._generate_subtask_tokens(
images, img_masks, tokens, masks, tokenizer, max_subtask_tokens, device
)
# Decode and print the generated subtask tokens
for i in range(bsize):
# Remove padding tokens (0) and special tokens
valid_tokens = generated_subtask_tokens[i][generated_subtask_tokens[i] != 0]
decoded_text = tokenizer.decode(valid_tokens, skip_special_tokens=True)
print(f"[Inference] Generated subtask {i}: {decoded_text}")
# Create mask for generated tokens (all valid)
subtask_masks = torch.ones_like(generated_subtask_tokens, dtype=torch.bool)
# During inference, we don't have subtask_tokens yet, so pass None
# Also no FAST tokens during inference
prefix_embs, prefix_pad_masks, prefix_att_masks, _, _, _ = self.embed_prefix(
images, img_masks, tokens, subtask_tokens=generated_subtask_tokens, masks=masks, subtask_masks=subtask_masks,
fast_action_tokens=None, fast_action_masks=None
)
# Convert embeddings to bfloat16 if needed for the model
if (
self.paligemma_with_expert.paligemma.language_model.layers[0].self_attn.q_proj.weight.dtype
== torch.bfloat16
):
prefix_embs = prefix_embs.to(dtype=torch.bfloat16)
# prefix_att_masks is already a 2D attention mask from embed_prefix
prefix_position_ids = torch.cumsum(prefix_pad_masks, dim=1) - 1
prefix_att_2d_masks_4d = self._prepare_attention_masks_4d(prefix_att_2d_masks)
prefix_att_2d_masks_4d = self._prepare_attention_masks_4d(prefix_att_masks, dtype=prefix_embs.dtype)
self.paligemma_with_expert.paligemma.language_model.config._attn_implementation = "eager" # noqa: SLF001
_, past_key_values = self.paligemma_with_expert.forward(
@@ -850,7 +1427,7 @@ class PI05Pytorch(nn.Module): # see openpi `PI0Pytorch`
prefix_offsets = torch.sum(prefix_pad_masks, dim=-1)[:, None]
position_ids = prefix_offsets + torch.cumsum(suffix_pad_masks, dim=1) - 1
full_att_2d_masks_4d = self._prepare_attention_masks_4d(full_att_2d_masks)
full_att_2d_masks_4d = self._prepare_attention_masks_4d(full_att_2d_masks, dtype=suffix_embs.dtype)
self.paligemma_with_expert.gemma_expert.model.config._attn_implementation = "eager" # noqa: SLF001
outputs_embeds, _ = self.paligemma_with_expert.forward(
@@ -896,6 +1473,14 @@ class PI05Policy(PreTrainedPolicy):
self.model.to(config.device)
# Load tokenizer for subtask decoding
try:
from transformers import AutoTokenizer
self.tokenizer = AutoTokenizer.from_pretrained("google/paligemma-3b-pt-224")
except Exception as e:
logging.warning(f"Could not load tokenizer for subtask decoding: {e}")
self.tokenizer = None
self.reset()
@classmethod
@@ -990,7 +1575,7 @@ class PI05Policy(PreTrainedPolicy):
print(f"Remapped {remap_count} state dict keys")
# Load the remapped state dict into the model
missing_keys, unexpected_keys = model.load_state_dict(remapped_state_dict, strict=strict)
missing_keys, unexpected_keys = model.load_state_dict(remapped_state_dict, strict=False)
if missing_keys:
print(f"Missing keys when loading state dict: {len(missing_keys)} keys")
@@ -1195,10 +1780,16 @@ class PI05Policy(PreTrainedPolicy):
# Prepare inputs
images, img_masks = self._preprocess_images(batch)
tokens, masks = batch[f"{OBS_LANGUAGE_TOKENS}"], batch[f"{OBS_LANGUAGE_ATTENTION_MASK}"]
# Use high_level_task tokens (WITHOUT subtask) for inference - we'll generate the subtask
high_level_task = batch[f"{OBS_LANGUAGE_HIGH_LEVEL_TASK_TOKENS}"]
high_level_task_masks = batch[f"{OBS_LANGUAGE_HIGH_LEVEL_TASK_ATTENTION_MASK}"]
# Sample actions using the model (pass through RTC kwargs, no separate state needed for PI05)
actions = self.model.sample_actions(images, img_masks, tokens, masks, **kwargs)
actions = self.model.sample_actions(
images, img_masks, high_level_task, high_level_task_masks,
tokenizer=self.tokenizer,
**kwargs
)
# Unpad actions to actual action dimension
original_action_dim = self.config.output_features[ACTION].shape[0]
@@ -1211,22 +1802,42 @@ class PI05Policy(PreTrainedPolicy):
# Prepare inputs
images, img_masks = self._preprocess_images(batch)
tokens, masks = batch[f"{OBS_LANGUAGE_TOKENS}"], batch[f"{OBS_LANGUAGE_ATTENTION_MASK}"]
high_level_task = batch[f"{OBS_LANGUAGE_HIGH_LEVEL_TASK_TOKENS}"]
high_level_task_masks = batch[f"{OBS_LANGUAGE_HIGH_LEVEL_TASK_ATTENTION_MASK}"]
subtask_tokens, subtask_masks = batch[f"{OBS_LANGUAGE_SUBTASK_ONLY_TOKENS}"], batch[f"{OBS_LANGUAGE_SUBTASK_ONLY_ATTENTION_MASK}"]
actions = self.prepare_action(batch)
# Decode and print ground truth subtask tokens during training
# if self.tokenizer is not None and self.training:
# bsize = subtask_tokens.shape[0]
# for i in range(bsize):
# # Remove padding tokens (0) and special tokens
# valid_tokens = subtask_tokens[i][subtask_masks[i].bool()]
# # if len(valid_tokens) > 0:
# # decoded_text = self.tokenizer.decode(valid_tokens, skip_special_tokens=True)
# # print(f"[Training] Ground truth subtask {i}: {decoded_text}")
# Get FAST action tokens from batch
fast_action_tokens = batch.get("action.tokens", None) # (B, max_action_tokens)
fast_action_masks = batch.get("action.token_mask", None) # (B, max_action_tokens)
# Compute loss (no separate state needed for PI05)
losses = self.model.forward(images, img_masks, tokens, masks, actions)
# high_level_task = instruction tokens WITHOUT subtask (e.g., "High level task: X; State: Y; Subtask:")
# subtask_tokens = subtask tokens to predict (e.g., "pick up the cup")
# fast_action_tokens = discrete action token IDs to predict
loss_dict = self.model.forward(
images, img_masks, high_level_task, high_level_task_masks, subtask_tokens, subtask_masks, actions,
fast_action_tokens=fast_action_tokens, fast_action_masks=fast_action_masks
)
# Truncate losses to actual action dimensions
original_action_dim = self.config.output_features[ACTION].shape[0]
losses = losses[:, :, :original_action_dim]
# Extract the total loss
loss = loss_dict["loss"]
loss = losses.mean()
loss_dict = {
# Prepare detailed loss dictionary for logging
detailed_loss_dict = {
"loss": loss.item(),
"loss_per_dim": losses.mean(dim=[0, 1]).detach().cpu().numpy().tolist(),
"flow_loss": loss_dict["flow_loss"].mean().item(),
"subtask_loss": loss_dict["subtask_loss"].item(),
"fast_loss": loss_dict["fast_loss"].item(),
}
return loss, loss_dict
return loss, detailed_loss_dict

53
src/lerobot/policies/pi05/processor_pi05.py
View File

@@ -33,6 +33,7 @@ from lerobot.processor import (
ProcessorStep,
ProcessorStepRegistry,
RenameObservationsProcessorStep,
ActionTokenizerProcessorStep,
TokenizerProcessorStep,
UnnormalizerProcessorStep,
)
@@ -47,13 +48,15 @@ from lerobot.utils.constants import (
@ProcessorStepRegistry.register(name="pi05_prepare_state_tokenizer_processor_step")
@dataclass
class Pi05PrepareStateTokenizerProcessorStep(ProcessorStep):
class Pi05PrepareStateAndLanguageTokenizerProcessorStep(ProcessorStep):
"""
Processor step to prepare the state and tokenize the language input.
"""
max_state_dim: int = 32
task_key: str = "task"
high_level_task_key: str = "user_prompt"
subtask_only_key: str = "subtask"
def __call__(self, transition: EnvTransition) -> EnvTransition:
transition = transition.copy()
@@ -65,6 +68,8 @@ class Pi05PrepareStateTokenizerProcessorStep(ProcessorStep):
if tasks is None:
raise ValueError("No task found in complementary data")
high_level_tasks = transition.get(TransitionKey.COMPLEMENTARY_DATA, {}).get(self.high_level_task_key)
# TODO: check if this necessary
state = deepcopy(state)
@@ -76,16 +81,42 @@ class Pi05PrepareStateTokenizerProcessorStep(ProcessorStep):
state_np = state.cpu().numpy()
discretized_states = np.digitize(state_np, bins=np.linspace(-1, 1, 256 + 1)[:-1]) - 1
full_prompts = []
# Clean high level tasks first (if available)
cleaned_high_level_tasks = []
if high_level_tasks is not None:
for high_level_task in high_level_tasks:
cleaned_high_level_tasks.append(high_level_task.strip().replace("_", " ").replace("\n", " "))
# Process low level tasks with state information
low_level_prompts = []
subtask_only_prompts = [] # Store only the subtask text for prediction
for i, task in enumerate(tasks):
cleaned_text = task.strip().replace("_", " ").replace("\n", " ")
state_str = " ".join(map(str, discretized_states[i]))
full_prompt = f"Task: {cleaned_text}, State: {state_str};\nAction: "
full_prompts.append(full_prompt)
transition[TransitionKey.COMPLEMENTARY_DATA][self.task_key] = full_prompts
# Normalize state to [-1, 1] range if needed (assuming it's already normalized by normalizer processor step!!)
# Discretize into 256 bins (see openpi `PaligemmaTokenizer.tokenize()`)
# Store only the subtask text (used as prediction target)
subtask_only_prompts.append(cleaned_text)
if cleaned_high_level_tasks:
cleaned_high_level_task = cleaned_high_level_tasks[i]
full_prompt = f"High level task: {cleaned_high_level_task}; State: {state_str}; Subtask: {cleaned_text}"
else:
full_prompt = f"Task: {cleaned_text}, State: {state_str};\nAction: "
low_level_prompts.append(full_prompt)
transition[TransitionKey.COMPLEMENTARY_DATA][self.task_key] = low_level_prompts
transition[TransitionKey.COMPLEMENTARY_DATA][self.subtask_only_key] = subtask_only_prompts
# Process high level tasks without state information (if available)
if high_level_tasks is not None:
high_level_prompts = []
for i, cleaned_high_level_task in enumerate(cleaned_high_level_tasks):
state_str = " ".join(map(str, discretized_states[i]))
full_prompt = f"High level task: {cleaned_high_level_task}; State: {state_str}; Subtask:"
high_level_prompts.append(full_prompt)
transition[TransitionKey.COMPLEMENTARY_DATA][self.high_level_task_key] = high_level_prompts
return transition
def transform_features(
@@ -128,25 +159,27 @@ def make_pi05_pre_post_processors(
Returns:
A tuple containing the configured pre-processor and post-processor pipelines.
"""
# Add remaining processors
input_steps: list[ProcessorStep] = [
RenameObservationsProcessorStep(rename_map={}), # To mimic the same processor as pretrained one
AddBatchDimensionProcessorStep(),
# NOTE: NormalizerProcessorStep MUST come before Pi05PrepareStateTokenizerProcessorStep
# NOTE: NormalizerProcessorStep MUST come before Pi05PrepareStateAndLanguageTokenizerProcessorStep
# because the tokenizer step expects normalized state in [-1, 1] range for discretization
NormalizerProcessorStep(
features={**config.input_features, **config.output_features},
norm_map=config.normalization_mapping,
stats=dataset_stats,
),
Pi05PrepareStateTokenizerProcessorStep(max_state_dim=config.max_state_dim),
Pi05PrepareStateAndLanguageTokenizerProcessorStep(max_state_dim=config.max_state_dim),
TokenizerProcessorStep(
tokenizer_name="google/paligemma-3b-pt-224",
max_length=config.tokenizer_max_length,
padding_side="right",
padding="max_length",
),
ActionTokenizerProcessorStep(
tokenizer_name="/fsx/jade_choghari/outputs/fast_tokenizer", # TODO: jade put the PI
),
DeviceProcessorStep(device=config.device),
]

22
src/lerobot/policies/pi05/train.sh Normal file
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@@ -0,0 +1,22 @@
export CUDA_LAUNCH_BLOCKING=1
lerobot-train \
--dataset.repo_id=local \
--dataset.root=/fsx/jade_choghari/outputs/collect-data-pgen \
--output_dir=/fsx/jade_choghari/outputs/pi0_fast_fruit1 \
--job_name=pi0_training \
--policy.repo_id=jade_choghari/pi0-base1 \
--policy.path=lerobot/pi05_base \
--policy.dtype=bfloat16 \
--steps=200000 \
--save_freq=5000 \
--rename_map='{
"observation.images.base": "observation.images.base_0_rgb",
"observation.images.left_wrist": "observation.images.left_wrist_0_rgb",
"observation.images.right_wrist": "observation.images.right_wrist_0_rgb",
}' \
--batch_size=4 \
--policy.device=cuda \
--wandb.enable=true \
--wandb.disable_artifact=true \
--wandb.project=pi05hi-training \
# /fsx/jade_choghari/.cache/huggingface/lerobot/jadechoghari/collect-data

18
src/lerobot/policies/pi05/train2.sh Normal file
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@@ -0,0 +1,18 @@
rm -rf /fsx/jade_choghari/outputs/pi0_multi_training
lerobot-train \
--dataset.repo_id=local\
--dataset.root=/fsx/jade_choghari/outputs/collect-data-pgen \
--output_dir=/fsx/jade_choghari/outputs/pi0_multi_training \
--job_name=pi0_multi_training \
--policy.repo_id=jadechoghari/pi0-base1 \
--policy.path=lerobot/pi05_base \
--policy.dtype=bfloat16 \
--steps=50000 \
--save_freq=5000 \
--rename_map='{
"observation.images.base": "observation.images.base_0_rgb",
"observation.images.left_wrist": "observation.images.left_wrist_0_rgb",
"observation.images.right_wrist": "observation.images.right_wrist_0_rgb",
}' \
--batch_size=32 \
--policy.device=cuda \

9
src/lerobot/policies/pi05/train_fast.sh Normal file
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@@ -0,0 +1,9 @@
python src/lerobot/policies/pi05/train_fast_tokenizer.py \
--repo_id "local" \
--root "/fsx/jade_choghari/outputs/collect-data-pgen" \
--action_horizon 16 \
--encoded_dims "0:15" \
--action_horizon 50 \
--vocab_size 1024 \
--scale 10.0 \
--output_dir "/fsx/jade_choghari/outputs/fast_tokenizer"

410
src/lerobot/policies/pi05/train_fast_tokenizer.py Normal file
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@@ -0,0 +1,410 @@
"""Train FAST tokenizer for action encoding.
This script:
1. Loads action chunks from LeRobotDataset (with sampling)
2. Applies delta transforms and per-timestamp normalization
3. Trains FAST tokenizer on specified action dimensions
4. Saves tokenizer to assets directory
5. Reports compression statistics
"""
import json
import numpy as np
import tyro
from pathlib import Path
from transformers import AutoProcessor
import torch
from lerobot.datasets.lerobot_dataset import LeRobotDataset
def apply_delta_transform(state: np.ndarray, actions: np.ndarray, delta_dims: list[int] | None) -> np.ndarray:
"""Apply delta transform to specified dimensions.
Args:
state: Current state [D]
actions: Future actions [D]
delta_dims: List of dimension indices to apply delta transform to
Returns:
Transformed actions [D]
"""
if delta_dims is None or len(delta_dims) == 0:
return actions
delta_actions = actions.copy()
for dim in delta_dims:
delta_actions[dim] = actions[dim] - state[dim]
return delta_actions
def process_episode(args):
"""Process single episode and return action chunks."""
dataset, ep_idx, action_horizon, delta_dims, sample_fraction, state_key, use_delta_transform = args
try:
# Get episode info
ep_info = dataset.meta.episodes[ep_idx]
from_idx = ep_info["dataset_from_index"]
to_idx = ep_info["dataset_to_index"]
ep_length = to_idx - from_idx
if ep_length < action_horizon:
return None
# Load all frames in episode
# If dataset has episode filtering, we need to use the mapping
states = []
actions = []
for abs_idx in range(from_idx, to_idx):
# Map absolute index to relative index if needed
if dataset._absolute_to_relative_idx is not None:
if abs_idx not in dataset._absolute_to_relative_idx:
# This episode's frames aren't in the filtered dataset
return None
rel_idx = dataset._absolute_to_relative_idx[abs_idx]
else:
rel_idx = abs_idx
frame = dataset.hf_dataset[rel_idx]
# Get state (could be from observation.state or other state key)
if state_key in frame:
state = frame[state_key].numpy() if torch.is_tensor(frame[state_key]) else np.array(frame[state_key])
else:
# If no state key, use zeros (no delta transform)
state = np.zeros_like(frame["action"].numpy() if torch.is_tensor(frame["action"]) else np.array(frame["action"]))
action = frame["action"].numpy() if torch.is_tensor(frame["action"]) else np.array(frame["action"])
states.append(state)
actions.append(action)
states = np.array(states)
actions = np.array(actions)
# Create action chunks (sliding window)
# All actions in a chunk are relative to the FIRST state in that chunk
action_chunks = []
for i in range(len(states) - action_horizon + 1):
current_state = states[i] # First state in chunk
future_absolute_actions = actions[i:i + action_horizon]
if use_delta_transform:
# Relative actions
delta_chunk = np.zeros_like(future_absolute_actions)
for t in range(action_horizon):
delta_chunk[t] = apply_delta_transform(
current_state,
future_absolute_actions[t],
delta_dims,
)
action_chunks.append(delta_chunk)
else:
# Absolute actions (NO delta)
action_chunks.append(future_absolute_actions)
if len(action_chunks) == 0:
return None
action_chunks = np.array(action_chunks)
# Sample chunks
if sample_fraction < 1.0:
n_chunks = len(action_chunks)
n_samples = max(1, int(n_chunks * sample_fraction))
episode_seed = hash(ep_idx) % (2**31)
rng = np.random.RandomState(episode_seed)
indices = rng.choice(n_chunks, size=n_samples, replace=False)
action_chunks = action_chunks[indices]
return action_chunks
except Exception as e:
print(f"Error processing episode {ep_idx}: {e}")
import traceback
traceback.print_exc()
return None
def train_fast_tokenizer(
action_chunks: np.ndarray,
vocab_size: int = 1024,
scale: float = 10.0,
) -> AutoProcessor:
"""
Train FAST tokenizer (BPE on DCT coefficients) on action chunks.
Uses the .fit() method to train a new tokenizer on the provided data.
Args:
action_chunks: Array of action chunks [N, H, D] where N=num_chunks, H=horizon, D=action_dim
vocab_size: BPE vocabulary size
scale: DCT scaling factor for quantization
Returns:
Trained FAST tokenizer
"""
print(f"Training FAST tokenizer on {len(action_chunks)} action chunks...")
print(f"Action chunk shape: {action_chunks.shape}")
print(f"Vocab size: {vocab_size}")
print(f"DCT scale: {scale}")
# Download the tokenizer source code (not pretrained weights)
# We'll train a new tokenizer on our own data
base_tokenizer = AutoProcessor.from_pretrained(
"physical-intelligence/fast",
trust_remote_code=True
)
# Convert action_chunks array to list of arrays (expected by .fit())
action_data_list = [action_chunks[i] for i in range(len(action_chunks))]
# Train the new tokenizer on our action data using .fit()
# This trains the BPE tokenizer on DCT coefficients
print("Training new tokenizer (this may take a few minutes)...")
tokenizer = base_tokenizer.fit(
action_data_list,
scale=scale,
vocab_size=vocab_size,
time_horizon=action_chunks.shape[1], # action_horizon
action_dim=action_chunks.shape[2], # encoded dimensions
)
print("✓ Tokenizer training complete!")
# Validate it works
sample_chunk = action_chunks[0]
encoded = tokenizer(sample_chunk[None])[0]
if isinstance(encoded, list):
encoded = np.array(encoded)
print(f"Sample encoding: {len(encoded)} tokens for chunk shape {sample_chunk.shape}")
return tokenizer
def compute_compression_stats(tokenizer, action_chunks: np.ndarray):
"""Compute compression statistics."""
print("\nComputing compression statistics...")
# Sample for stats (use max 1000 chunks for speed)
sample_size = min(1000, len(action_chunks))
sample_indices = np.random.RandomState(42).choice(len(action_chunks), size=sample_size, replace=False)
sample_chunks = action_chunks[sample_indices]
token_lengths = []
for chunk in sample_chunks:
encoded = tokenizer(chunk[None])[0]
if isinstance(encoded, list):
token_lengths.append(len(encoded))
else:
token_lengths.append(encoded.shape[0] if hasattr(encoded, 'shape') else len(encoded))
token_lengths = np.array(token_lengths)
# Compression ratio: (H * D) / avg_tokens
input_size = action_chunks.shape[1] * action_chunks.shape[2]
avg_tokens = np.mean(token_lengths)
compression_ratio = input_size / avg_tokens
stats = {
'compression_ratio': float(compression_ratio),
'mean_token_length': float(np.mean(token_lengths)),
'p99_token_length': float(np.percentile(token_lengths, 99)),
'min_token_length': float(np.min(token_lengths)),
'max_token_length': float(np.max(token_lengths)),
}
print(f"Compression Statistics:")
print(f" Average compression ratio: {stats['compression_ratio']:.2f}x")
print(f" Mean token length: {stats['mean_token_length']:.1f}")
print(f" P99 token length: {stats['p99_token_length']:.0f}")
print(f" Min token length: {stats['min_token_length']:.0f}")
print(f" Max token length: {stats['max_token_length']:.0f}")
return stats
def main(
repo_id: str,
root: str | None = None,
action_horizon: int = 10,
max_episodes: int | None = None,
sample_fraction: float = 0.1,
encoded_dims: str = "0:6,7:23",
delta_dims: str | None = None,
use_delta_transform: bool = False,
state_key: str = "observation.state",
vocab_size: int = 1024,
scale: float = 10.0,
output_dir: str | None = None,
):
"""
Train FAST tokenizer for action encoding.
Args:
repo_id: LeRobot dataset repository ID
root: Root directory for dataset (default: ~/.cache/huggingface/lerobot)
action_horizon: Number of future actions in each chunk
max_episodes: Max episodes to use (None = all episodes in dataset)
sample_fraction: Fraction of chunks to sample per episode
encoded_dims: Comma-separated dimension ranges to encode (e.g., "0:6,7:23")
delta_dims: Comma-separated dimension indices for delta transform (e.g., "0,1,2,3,4,5")
use_delta_transform: Whether to apply delta transform (relative actions vs absolute actions)
state_key: Dataset key for state observations (default: "observation.state")
vocab_size: FAST vocabulary size (BPE vocab size)
scale: DCT scaling factor (default: 10.0)
output_dir: Directory to save tokenizer (default: ./fast_tokenizer_{repo_id})
"""
# Load dataset
print(f"Loading dataset: {repo_id}")
dataset = LeRobotDataset(repo_id=repo_id, root=root)
print(f"Dataset loaded: {dataset.num_episodes} episodes, {dataset.num_frames} frames")
# Parse encoded dimensions
encoded_dim_ranges = []
for range_str in encoded_dims.split(','):
start, end = map(int, range_str.strip().split(':'))
encoded_dim_ranges.append((start, end))
total_encoded_dims = sum(end - start for start, end in encoded_dim_ranges)
print(f"Encoding {total_encoded_dims} dimensions: {encoded_dims}")
# Parse delta dimensions
delta_dim_list = None
if delta_dims is not None and delta_dims.strip():
delta_dim_list = [int(d.strip()) for d in delta_dims.split(',')]
print(f"Delta dimensions: {delta_dim_list}")
else:
print("No delta dimensions specified")
print(f"Use delta transform: {use_delta_transform}")
if use_delta_transform and (delta_dim_list is None or len(delta_dim_list) == 0):
print("Warning: use_delta_transform=True but no delta_dims specified. No delta will be applied.")
print(f"Action horizon: {action_horizon}")
print(f"State key: {state_key}")
# Determine episodes to process
num_episodes = dataset.num_episodes
if max_episodes is not None:
num_episodes = min(max_episodes, num_episodes)
print(f"Processing {num_episodes} episodes...")
# Process episodes sequentially (to avoid pickling issues with dataset)
all_chunks = []
for ep_idx in range(num_episodes):
if ep_idx % 10 == 0:
print(f" Processing episode {ep_idx}/{num_episodes}...")
chunks = process_episode(
(dataset, ep_idx, action_horizon, delta_dim_list, sample_fraction, state_key, use_delta_transform)
)
if chunks is not None:
all_chunks.append(chunks)
# Concatenate all chunks
all_chunks = np.concatenate(all_chunks, axis=0)
print(f"Collected {len(all_chunks)} action chunks")
# Extract only encoded dimensions FIRST (before normalization)
encoded_chunks = []
for start, end in encoded_dim_ranges:
encoded_chunks.append(all_chunks[:, :, start:end])
encoded_chunks = np.concatenate(encoded_chunks, axis=-1) # [N, H, D_encoded]
print(f"Extracted {encoded_chunks.shape[-1]} encoded dimensions")
# Apply normalization to encoded dimensions only
# NOTE: For FAST, we ALWAYS use QUANTILE normalization (no per-timestamp)
# This clips outliers and provides consistent [-1, 1] range for DCT compression
print(f"\nBefore normalization - overall stats:")
print(f" Min: {np.min(encoded_chunks):.4f}, Max: {np.max(encoded_chunks):.4f}")
print(f" Mean: {np.mean(encoded_chunks):.4f}, Std: {np.std(encoded_chunks):.4f}")
norm_stats = dataset.meta.stats
if norm_stats is not None and "action" in norm_stats:
action_stats = norm_stats["action"]
# Build encoded dimension indices
encoded_dim_indices = []
for start, end in encoded_dim_ranges:
encoded_dim_indices.extend(range(start, end))
encoded_dim_indices = np.array(encoded_dim_indices)
# Use QUANTILE normalization: clip to [q01, q99] and map to [-1, 1]
if "q01" in action_stats and "q99" in action_stats:
q01 = np.array(action_stats["q01"])[encoded_dim_indices] # [D_encoded]
q99 = np.array(action_stats["q99"])[encoded_dim_indices] # [D_encoded]
print(f"\nNormalization stats (q01, q99) for encoded dimensions:")
for i, dim_idx in enumerate(encoded_dim_indices):
print(f" Orig dim {dim_idx}: q01={q01[i]:7.4f}, q99={q99[i]:7.4f}, range={q99[i]-q01[i]:7.4f}")
# Clip to quantile range and normalize to [-1, 1]
encoded_chunks = np.clip(encoded_chunks, q01, q99)
encoded_chunks = 2.0 * (encoded_chunks - q01) / np.maximum(q99 - q01, 1e-6) - 1.0
print(f"\nApplied quantile normalization [q01, q99] → [-1, 1]")
print(f"\nAfter normalization - overall stats:")
print(f" Min: {np.min(encoded_chunks):.4f}, Max: {np.max(encoded_chunks):.4f}")
print(f" Mean: {np.mean(encoded_chunks):.4f}, Std: {np.std(encoded_chunks):.4f}")
print(f"\nPer-dimension stats (after normalization):")
for d in range(encoded_chunks.shape[-1]):
dim_data = encoded_chunks[:, :, d]
print(f" Dim {d}: min={np.min(dim_data):7.4f}, max={np.max(dim_data):7.4f}, "
f"mean={np.mean(dim_data):7.4f}, std={np.std(dim_data):7.4f}")
else:
print("Warning: q01/q99 stats not found, using raw actions")
else:
print("Warning: No normalization stats found, using raw actions")
print(f"Encoded chunks shape: {encoded_chunks.shape}")
# Train FAST tokenizer
tokenizer = train_fast_tokenizer(
encoded_chunks,
vocab_size=vocab_size,
scale=scale,
)
# Compute compression statistics
compression_stats = compute_compression_stats(tokenizer, encoded_chunks)
# Save tokenizer
if output_dir is None:
output_dir = f"fast_tokenizer_{repo_id.replace('/', '_')}"
output_path = Path(output_dir)
output_path.mkdir(parents=True, exist_ok=True)
tokenizer.save_pretrained(output_path)
# Save metadata
metadata = {
'repo_id': repo_id,
'vocab_size': vocab_size,
'scale': scale,
'encoded_dims': encoded_dims,
'encoded_dim_ranges': encoded_dim_ranges,
'total_encoded_dims': total_encoded_dims,
'delta_dims': delta_dims,
'delta_dim_list': delta_dim_list,
'use_delta_transform': use_delta_transform,
'state_key': state_key,
'action_horizon': action_horizon,
'num_training_chunks': len(encoded_chunks),
'compression_stats': compression_stats,
}
with open(output_path / "metadata.json", 'w') as f:
json.dump(metadata, f, indent=2)
print(f"\n✅ Saved FAST tokenizer to {output_path}")
print(f"Metadata: {json.dumps(metadata, indent=2)}")
if __name__ == "__main__":
tyro.cli(main)

101
src/lerobot/policies/pi05/train_fast_tokenizer_example.md Normal file
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@@ -0,0 +1,101 @@
# Train FAST Tokenizer - Usage Examples
This script trains a FAST (Factorized Action Sequence Tokenizer) on LeRobotDataset action data.
## Basic Usage
```bash
python src/lerobot/policies/pi05/train_fast_tokenizer.py \
--repo_id "lerobot/aloha_sim_insertion_human" \
--action_horizon 10 \
--encoded_dims "0:7" \
--vocab_size 1024 \
--scale 10.0
```
## Parameters
### Required
- `--repo_id`: LeRobot dataset repository ID (e.g., "lerobot/aloha_sim_insertion_human")
### Optional
- `--root`: Root directory for dataset (default: ~/.cache/huggingface/lerobot)
- `--action_horizon`: Number of future actions in each chunk (default: 10)
- `--max_episodes`: Maximum number of episodes to use (default: None = all)
- `--sample_fraction`: Fraction of chunks to sample per episode (default: 0.1)
- `--encoded_dims`: Comma-separated dimension ranges to encode (default: "0:6,7:23")
- Example: "0:7" encodes dimensions 0-6
- Example: "0:3,6:9" encodes dimensions 0-2 and 6-8
- `--delta_dims`: Comma-separated dimension indices for delta transform (default: None)
- Example: "0,1,2,3,4,5" applies delta transform to first 6 dimensions
- Delta transform: action[i] - state[i] for specified dimensions
- `--state_key`: Dataset key for state observations (default: "observation.state")
- `--vocab_size`: FAST vocabulary size / BPE vocab size (default: 1024)
- `--scale`: DCT scaling factor (default: 10.0)
- `--output_dir`: Directory to save tokenizer (default: ./fast_tokenizer_{repo_id})
## Examples
### Example 1: Train on full action space
```bash
python src/lerobot/policies/pi05/train_fast_tokenizer.py \
--repo_id "lerobot/pusht" \
--action_horizon 16 \
--encoded_dims "0:2" \
--vocab_size 512 \
--max_episodes 100
```
### Example 2: Train with delta transform
```bash
python src/lerobot/policies/pi05/train_fast_tokenizer.py \
--repo_id "lerobot/aloha_sim_insertion_human" \
--action_horizon 10 \
--encoded_dims "0:14" \
--delta_dims "0,1,2,3,4,5,6,7,8,9,10,11,12,13" \
--state_key "observation.state" \
--vocab_size 1024 \
--scale 10.0 \
--sample_fraction 0.2
```
### Example 3: Train on subset of dimensions
```bash
python src/lerobot/policies/pi05/train_fast_tokenizer.py \
--repo_id "lerobot/aloha_sim_insertion_human" \
--action_horizon 10 \
--encoded_dims "0:7" \
--vocab_size 1024 \
--output_dir "./my_tokenizer"
```
## Output
The script saves:
1. **Tokenizer files**: Trained FAST tokenizer (can be loaded with `AutoProcessor.from_pretrained()`)
2. **metadata.json**: Contains:
- Configuration parameters
- Compression statistics (compression ratio, token lengths)
- Training dataset information
## Understanding the Process
1. **Load Dataset**: Loads the LeRobotDataset from HuggingFace
2. **Extract Action Chunks**: Creates sliding windows of actions with specified horizon
3. **Apply Delta Transform**: (Optional) Computes action deltas relative to current state
4. **Select Encoded Dimensions**: Extracts only the dimensions to be encoded
5. **Normalize**: Applies quantile normalization ([q01, q99] → [-1, 1])
6. **Train Tokenizer**: Trains BPE tokenizer on DCT coefficients
7. **Compute Stats**: Reports compression ratio and token length statistics
8. **Save**: Saves tokenizer and metadata
## Notes
- **Normalization**: The script uses quantile normalization (q01, q99) from the dataset's statistics
- **Sampling**: To speed up training, you can sample a fraction of chunks per episode
- **Delta Transform**: Applied per-dimension to make actions relative to current state
- **Compression**: FAST uses DCT + BPE to compress action sequences efficiently

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src/lerobot/policies/pi05/train_multi.sh Normal file
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rm -rf /fsx/jade_choghari/outputs/pi0_multi_training
accelerate launch --multi_gpu --num_processes=2 \
$(which lerobot-train) \
--dataset.repo_id=local \
--dataset.root=/fsx/jade_choghari/outputs/collect-data-pgen \
--output_dir=/fsx/jade_choghari/outputs/pi0_multi_training \
--job_name=pi0_multi_training \
--policy.repo_id=jadechoghari/pi0-base1 \
--policy.path=lerobot/pi05_base \
--policy.dtype=bfloat16 \
--steps=50000 \
--save_freq=5000 \
--rename_map='{
"observation.images.base": "observation.images.base_0_rgb",
"observation.images.left_wrist": "observation.images.left_wrist_0_rgb",
"observation.images.right_wrist": "observation.images.right_wrist_0_rgb",
}' \
--policy.gradient_checkpointing=true \
--batch_size=1 \
--policy.device=cpu
# --wandb.enable=true \
# --wandb.disable_artifact=true \
# --wandb.project=pi05hi-training \

6
src/lerobot/policies/xvla/__init__.py Normal file
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@@ -0,0 +1,6 @@
# register the processor steps
from lerobot.policies.xvla.processor_xvla import (
XVLAAddDomainIdProcessorStep,
XVLAImageNetNormalizeProcessorStep,
XVLAImageToFloatProcessorStep,
)

588
src/lerobot/policies/xvla/action_hub.py Normal file
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@@ -0,0 +1,588 @@
# ------------------------------------------------------------------------------
# Copyright 2025 2toINF and HuggingFace Inc. (https://github.com/2toINF)
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
# ------------------------------------------------------------------------------
from __future__ import annotations
from collections.abc import Iterable
import torch
import torch.nn as nn
# =============================================================================
# Registry
# =============================================================================
ACTION_REGISTRY: dict[str, type[BaseActionSpace]] = {}
def register_action(name: str):
"""Decorator for registering a new action space."""
def _wrap(cls):
key = name.lower()
if key in ACTION_REGISTRY:
raise KeyError(f"ActionSpace '{key}' already registered -> {ACTION_REGISTRY[key]}")
ACTION_REGISTRY[key] = cls
cls.name = key
return cls
return _wrap
def build_action_space(name: str, **kwargs) -> BaseActionSpace:
"""Instantiate a registered action space by name."""
key = name.lower()
if key not in ACTION_REGISTRY:
raise KeyError(f"Unknown action space '{name}'. Available: {list(ACTION_REGISTRY.keys())}")
return ACTION_REGISTRY[key](**kwargs)
# =============================================================================
# Base class
# =============================================================================
class BaseActionSpace(nn.Module):
"""
Abstract base class for all action-space definitions.
Each subclass defines:
- `dim_action`: dimension of the action vector.
- `gripper_idx`: indices of gripper channels.
- `compute_loss(pred, target)`: supervised loss for this space.
- `preprocess(proprio, action, mode)`: pre-step modifications.
- `postprocess(action)`: post-step corrections (e.g. apply sigmoid).
"""
name: str = "base"
dim_action: int = 0
gripper_idx: tuple[int, ...] = ()
def __init__(self):
super().__init__()
# ---------------------------------------------------------------------
# Core supervised loss
# ---------------------------------------------------------------------
def compute_loss(self, pred: torch.Tensor, target: torch.Tensor) -> dict[str, torch.Tensor]:
raise NotImplementedError
def forward(self, pred: torch.Tensor, target: torch.Tensor) -> dict[str, torch.Tensor]:
"""Alias for compute_loss."""
return self.compute_loss(pred, target)
# ---------------------------------------------------------------------
# Space-level hooks
# ---------------------------------------------------------------------
def preprocess(
self,
proprio: torch.Tensor,
action: torch.Tensor,
mode: str = "train",
) -> tuple[torch.Tensor, torch.Tensor]:
"""Default: return unchanged."""
return proprio, action
def postprocess(self, action: torch.Tensor) -> torch.Tensor:
"""Default: return unchanged."""
return action
# =============================================================================
# Utilities
# =============================================================================
def _ensure_indices_valid(dim_action: int, idx: Iterable[int], name: str) -> None:
bad = [i for i in idx if i < 0 or i >= dim_action]
if bad:
raise IndexError(f"{name} contains out-of-range indices {bad} for action dim dim_action={dim_action}")
# =============================================================================
# Implementations
# =============================================================================
@register_action("ee6d")
class EE6DActionSpace(BaseActionSpace):
"""End-effector layout with xyz, 6D rotation, and gripper channels."""
dim_action = 20
gripper_idx = (9, 19)
GRIPPER_SCALE = 1.0
XYZ_SCALE = 500.0
ROT_SCALE = 10.0
POS_IDX_1 = (0, 1, 2)
POS_IDX_2 = (10, 11, 12)
ROT_IDX_1 = (3, 4, 5, 6, 7, 8)
ROT_IDX_2 = (13, 14, 15, 16, 17, 18)
def __init__(self):
super().__init__()
self.mse = nn.MSELoss()
self.bce = nn.BCEWithLogitsLoss()
def compute_loss(self, pred, target):
assert pred.shape == target.shape, "pred/target shapes must match"
batch_size, seq_len, action_dim = pred.shape
_ensure_indices_valid(action_dim, self.gripper_idx, "gripper_idx")
# Gripper BCE
g_losses = [self.bce(pred[:, :, gi], target[:, :, gi]) for gi in self.gripper_idx]
gripper_loss = sum(g_losses) / len(self.gripper_idx) * self.GRIPPER_SCALE
# XYZ position
pos_loss = (
self.mse(pred[:, :, self.POS_IDX_1], target[:, :, self.POS_IDX_1])
+ self.mse(pred[:, :, self.POS_IDX_2], target[:, :, self.POS_IDX_2])
) * self.XYZ_SCALE
# Rotation 6D
rot_loss = (
self.mse(pred[:, :, self.ROT_IDX_1], target[:, :, self.ROT_IDX_1])
+ self.mse(pred[:, :, self.ROT_IDX_2], target[:, :, self.ROT_IDX_2])
) * self.ROT_SCALE
return {
"position_loss": pos_loss,
"rotate6D_loss": rot_loss,
"gripper_loss": gripper_loss,
}
def preprocess(self, proprio, action, mode="train"):
"""Zero-out gripper channels in proprio/action."""
proprio_m = proprio.clone()
action_m = action.clone()
proprio_m[..., self.gripper_idx] = 0.0
action_m[..., self.gripper_idx] = 0.0
return proprio_m, action_m
def postprocess(self, action: torch.Tensor) -> torch.Tensor:
"""Apply sigmoid to gripper logits."""
if action.size(-1) > max(self.gripper_idx):
action[..., self.gripper_idx] = torch.sigmoid(action[..., self.gripper_idx])
return action
@register_action("joint")
class JointActionSpace(BaseActionSpace):
"""Joint-space layout with joints + gripper only."""
dim_action = 14
gripper_idx = (6, 13)
GRIPPER_SCALE = 0.1
JOINTS_SCALE = 1.0
def __init__(self):
super().__init__()
self.mse = nn.MSELoss()
self.bce = nn.BCEWithLogitsLoss()
def compute_loss(self, pred, target):
assert pred.shape == target.shape
batch_size, seq_len, action_dim = pred.shape
_ensure_indices_valid(action_dim, self.gripper_idx, "gripper_idx")
g_losses = [self.bce(pred[:, :, gi], target[:, :, gi]) for gi in self.gripper_idx]
gripper_loss = sum(g_losses) / len(self.gripper_idx) * self.GRIPPER_SCALE
joints_idx = tuple(i for i in range(action_dim) if i not in set(self.gripper_idx))
joints_loss = self.mse(pred[:, :, joints_idx], target[:, :, joints_idx]) * self.JOINTS_SCALE
return {
"joints_loss": joints_loss,
"gripper_loss": gripper_loss,
}
def preprocess(self, proprio, action, mode="train"):
"""Zero-out gripper channels in proprio/action."""
proprio_m = proprio.clone()
action_m = action.clone()
proprio_m[..., self.gripper_idx] = 0.0
action_m[..., self.gripper_idx] = 0.0
return proprio_m, action_m
def postprocess(self, action: torch.Tensor) -> torch.Tensor:
"""Apply sigmoid to gripper logits."""
if action.size(-1) > max(self.gripper_idx):
action[..., self.gripper_idx] = torch.sigmoid(action[..., self.gripper_idx])
return action
@register_action("agibot_ee6d")
class AGIBOTEE6DActionSpace(BaseActionSpace):
"""AGI-bot variant of EE6DActionSpace using MSE for all components."""
dim_action = 20
gripper_idx = (9, 19)
GRIPPER_SCALE = 10.0
XYZ_SCALE = 500.0
ROT_SCALE = 10.0
POS_IDX_1 = (0, 1, 2)
POS_IDX_2 = (10, 11, 12)
ROT_IDX_1 = (3, 4, 5, 6, 7, 8)
ROT_IDX_2 = (13, 14, 15, 16, 17, 18)
def __init__(self):
super().__init__()
self.mse = nn.MSELoss()
def compute_loss(self, pred, target):
assert pred.shape == target.shape
batch_size, seq_len, action_dim = pred.shape
_ensure_indices_valid(action_dim, self.gripper_idx, "gripper_idx")
gripper_loss = (
self.mse(pred[:, :, self.gripper_idx], target[:, :, self.gripper_idx]) * self.GRIPPER_SCALE
)
pos_loss = (
self.mse(pred[:, :, self.POS_IDX_1], target[:, :, self.POS_IDX_1])
+ self.mse(pred[:, :, self.POS_IDX_2], target[:, :, self.POS_IDX_2])
) * self.XYZ_SCALE
rot_loss = (
self.mse(pred[:, :, self.ROT_IDX_1], target[:, :, self.ROT_IDX_1])
+ self.mse(pred[:, :, self.ROT_IDX_2], target[:, :, self.ROT_IDX_2])
) * self.ROT_SCALE
return {
"position_loss": pos_loss,
"rotate6D_loss": rot_loss,
"gripper_loss": gripper_loss,
}
def preprocess(self, proprio, action, mode="train"):
"""No preprocessing applied in AGIBOT variant."""
return proprio, action
def postprocess(self, action: torch.Tensor) -> torch.Tensor:
"""AGIBOT does not postprocess."""
return action
@register_action("franka_joint7")
class FrankaJoint7ActionSpace(BaseActionSpace):
"""
Franka Panda joint-space: 7 joints, with gripper.
- Real robot action dim: 7
- Model-facing dim: 20 (padded with zeros)
compatible with pretrained VLA models expecting 20D.
"""
dim_action = 20 # model dimension
REAL_DIM = 7 # actual Franka joints
JOINTS_SCALE = 1.0
def __init__(self):
super().__init__()
self.mse = nn.MSELoss()
def _pad_to_model_dim(self, x: torch.Tensor) -> torch.Tensor:
"""Pad 7 → 20 dims (zeros for the dummy channels)."""
if x is None:
return None
if x.size(-1) == self.dim_action:
return x
if x.size(-1) != self.REAL_DIM:
raise ValueError(
f"Expected last dim to be {self.REAL_DIM} or {self.dim_action}, got {x.size(-1)}"
)
pad_shape = list(x.shape[:-1]) + [self.dim_action - self.REAL_DIM] # 13 zeros
pad = x.new_zeros(pad_shape)
return torch.cat([x, pad], dim=-1)
def _trim_to_real_dim(self, x: torch.Tensor) -> torch.Tensor:
"""Trim model output 20 → 7 dims."""
return x[..., : self.REAL_DIM]
def compute_loss(self, pred, target):
"""
pred : [B, T, 20]
target : [B, T, 7] or [B, T, 20]
Only compute MSE on the first 7 dims.
"""
pred = self._pad_to_model_dim(pred)
target = self._pad_to_model_dim(target)
assert pred.shape == target.shape
joints_loss = (
self.mse(
pred[:, :, : self.REAL_DIM], # use only the first 7 joints
target[:, :, : self.REAL_DIM],
)
* self.JOINTS_SCALE
)
return {"joints_loss": joints_loss}
def preprocess(self, proprio, action, mode="train"):
"""
During training:
- Pad [7] → [20]
"""
return proprio, self._pad_to_model_dim(action)
def postprocess(self, action: torch.Tensor) -> torch.Tensor:
"""
After model prediction:
- Trim [20] → [7] for real robot control.
"""
return self._trim_to_real_dim(action)
@register_action("auto")
class AutoActionSpace(BaseActionSpace):
"""
Auto-detecting action space that adapts to any action dimension.
- Auto-detects the real action dimension from the policy feature
- Model outputs max_dim for compatibility with pretrained models
- Loss is computed only on the first real_dim dimensions
- Postprocess trims output back to real_dim
Args:
real_dim: The actual action dimension from the dataset/policy feature
max_dim: The model's output dimension for pretrained VLA compatibility
"""
JOINTS_SCALE = 1.0
def __init__(self, real_dim: int, max_dim: int):
super().__init__()
self.real_dim = real_dim
self.dim_action = max_dim # Model-facing dimension
self.mse = nn.MSELoss()
def _pad_to_model_dim(self, x: torch.Tensor) -> torch.Tensor:
"""Pad real_dim → max_dim (zeros for the dummy channels)."""
if x is None:
return None
if x.size(-1) == self.dim_action:
return x
if x.size(-1) != self.real_dim:
# If dimension doesn't match either, pad/trim to real_dim first
if x.size(-1) < self.real_dim:
pad_shape = list(x.shape[:-1]) + [self.real_dim - x.size(-1)]
pad = x.new_zeros(pad_shape)
x = torch.cat([x, pad], dim=-1)
else:
x = x[..., : self.real_dim]
pad_shape = list(x.shape[:-1]) + [self.dim_action - self.real_dim]
pad = x.new_zeros(pad_shape)
return torch.cat([x, pad], dim=-1)
def _trim_to_real_dim(self, x: torch.Tensor) -> torch.Tensor:
"""Trim model output max_dim → real_dim."""
return x[..., : self.real_dim]
def compute_loss(self, pred: torch.Tensor, target: torch.Tensor) -> dict[str, torch.Tensor]:
"""
Compute loss only on the first real_dim dimensions.
pred: [B, T, max_dim] from the model
target: [B, T, real_dim] or [B, T, max_dim]
Loss = MSE(pred[:,:,:real_dim], target[:,:,:real_dim])
"""
pred = self._pad_to_model_dim(pred)
target = self._pad_to_model_dim(target)
assert pred.shape == target.shape, f"Shape mismatch: pred {pred.shape} vs target {target.shape}"
# only compute loss on the real dimensions
joints_loss = (
self.mse(
pred[:, :, : self.real_dim],
target[:, :, : self.real_dim],
)
* self.JOINTS_SCALE
)
return {"joints_loss": joints_loss}
def preprocess(self, proprio: torch.Tensor, action: torch.Tensor, mode: str = "train"):
"""
Pad action from real_dim to max_dim for the model.
"""
return proprio, self._pad_to_model_dim(action)
def postprocess(self, action: torch.Tensor) -> torch.Tensor:
"""
Trim model output from max_dim to real_dim for real robot control.
"""
return self._trim_to_real_dim(action)
@register_action("so101_bimanual")
class BimanualSO101ActionSpace(BaseActionSpace):
"""
Bimanual SO101 robot: 2 arms with 5 joints each + gripper.
Layout (real robot):
[left_arm (5 joints + gripper), right_arm (5 joints + gripper)]
- Left arm: shoulder_pan, shoulder_lift, elbow_flex, wrist_flex, wrist_roll, gripper
- Right arm: shoulder_pan, shoulder_lift, elbow_flex, wrist_flex, wrist_roll, gripper
Real action dim: 12
Model-facing dim: 20 (extra 8 dummy dims at the end)
"""
# Model output / training dimension (to match pretrained policy)
dim_action = 20
# Real robot action dimension
REAL_DIM = 12
# Indices of real vs dummy channels
REAL_IDXS = tuple(range(REAL_DIM)) # 0..11
DUMMY_IDXS = tuple(range(REAL_DIM, dim_action)) # 12..19
# Grippers live in the real part
gripper_idx = (5, 11) # left_gripper at idx 5, right_gripper at idx 11
GRIPPER_SCALE = 1.0
JOINTS_SCALE = 1.0
# Indices for left and right arm joints (excluding grippers)
LEFT_ARM_JOINTS = (0, 1, 2, 3, 4)
RIGHT_ARM_JOINTS = (6, 7, 8, 9, 10)
def __init__(self):
super().__init__()
self.mse = nn.MSELoss()
self.bce = nn.BCEWithLogitsLoss()
# ---------- helpers ----------
def _pad_to_model_dim(self, x: torch.Tensor) -> torch.Tensor:
"""If last dim is REAL_DIM (12), pad zeros to reach dim_action (20)."""
if x is None:
return None
if x.size(-1) == self.dim_action:
return x
if x.size(-1) != self.REAL_DIM:
raise ValueError(
f"Expected last dim to be {self.REAL_DIM} or {self.dim_action}, got {x.size(-1)}"
)
pad_shape = list(x.shape[:-1]) + [self.dim_action - self.REAL_DIM]
pad = x.new_zeros(pad_shape)
return torch.cat([x, pad], dim=-1)
def _trim_to_real_dim(self, x: torch.Tensor) -> torch.Tensor:
"""Keep only the first REAL_DIM (12) dims for the real robot."""
return x[..., : self.REAL_DIM]
# ---------- loss ----------
def compute_loss(self, pred, target):
"""
pred: [B, T, 20] from the model
target: [B, T, 12] or [B, T, 20]
We pad target → 20 and compute loss only on the real dims.
"""
# Ensure both are [B, T, 20]
pred = self._pad_to_model_dim(pred)
target = self._pad_to_model_dim(target)
assert pred.shape == target.shape
# ---- MSE for all real dims (011) ----
real_dims = 12
joints_loss = (
self.mse(
pred[:, :, :real_dims],
target[:, :, :real_dims],
)
* self.JOINTS_SCALE
)
left_arm_loss = self.mse(pred[:, :, :6], target[:, :, :6])
right_arm_loss = self.mse(pred[:, :, 6:12], target[:, :, 6:12])
gripper_loss = (
self.mse(
pred[:, :, [5, 11]],
target[:, :, [5, 11]],
)
* self.GRIPPER_SCALE
)
return {
"joints_loss": joints_loss,
"gripper_loss": gripper_loss,
"left_arm_loss": left_arm_loss,
"right_arm_loss": right_arm_loss,
}
# ---------- preprocess / postprocess ----------
def preprocess(self, proprio, action, mode="train"):
"""
- If proprio/action are 12-dim, pad them to 20 for the model.
- Zero-out gripper channels in proprio/action to focus learning on joints.
"""
proprio_m = self._pad_to_model_dim(proprio.clone())
action_m = self._pad_to_model_dim(action.clone()) if action is not None else None
proprio_m[..., self.gripper_idx] = 0.0
if action_m is not None:
action_m[..., self.gripper_idx] = 0.0
return proprio_m, action_m
def postprocess(self, action: torch.Tensor) -> torch.Tensor:
"""
- Model outputs [*, 20]
- Apply sigmoid to gripper logits
- Return only the first 12 dims for the real robot:
["left_shoulder_pan.pos",
"left_shoulder_lift.pos",
"left_elbow_flex.pos",
"left_wrist_flex.pos",
"left_wrist_roll.pos",
"left_gripper.pos",
"right_shoulder_pan.pos",
"right_shoulder_lift.pos",
"right_elbow_flex.pos",
"right_wrist_flex.pos",
"right_wrist_roll.pos",
"right_gripper.pos"]
"""
# Ensure we at least have the real dims + grippers
if action.size(-1) < self.REAL_DIM:
raise ValueError(f"Expected at least {self.REAL_DIM} dims in action, got {action.size(-1)}")
# Apply sigmoid on gripper channels in model space (indices 5 and 11)
if action.size(-1) > max(self.gripper_idx):
action[..., self.gripper_idx] = torch.sigmoid(action[..., self.gripper_idx])
# Return only the real 12-dim control vector for the env
return self._trim_to_real_dim(action)
# =============================================================================
# Exports
# =============================================================================
__all__ = [
"BaseActionSpace",
"build_action_space",
"register_action",
"EE6DActionSpace",
"JointActionSpace",
"AGIBOTEE6DActionSpace",
"FrankaJoint7ActionSpace",
"AutoActionSpace",
"BimanualSO101ActionSpace",
"ACTION_REGISTRY",
]

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# Copyright 2024 Microsoft and the HuggingFace Inc. team. All rights reserved.
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
import warnings
from transformers.configuration_utils import PretrainedConfig
from transformers.utils import logging
""" Florence-2 configuration"""
logger = logging.get_logger(__name__)
class Florence2VisionConfig(PretrainedConfig):
r"""
This is the configuration class to store the configuration of a [`Florence2VisionModel`]. It is used to instantiate a Florence2VisionModel
according to the specified arguments, defining the model architecture. Instantiating a configuration with the
defaults will yield a similar configuration to that of the Florence2VisionModel architecture.
Configuration objects inherit from [`PretrainedConfig`] and can be used to control the model outputs. Read the
documentation from [`PretrainedConfig`] for more information.
Args:
drop_path_rate (`float`, *optional*, defaults to 0.1):
The dropout rate of the drop path layer.
patch_size (`List[int]`, *optional*, defaults to [7, 3, 3, 3]):
The patch size of the image.
patch_stride (`List[int]`, *optional*, defaults to [4, 2, 2, 2]):
The patch stride of the image.
patch_padding (`List[int]`, *optional*, defaults to [3, 1, 1, 1]):
The patch padding of the image.
patch_prenorm (`List[bool]`, *optional*, defaults to [false, true, true, true]):
Whether to apply layer normalization before the patch embedding layer.
enable_checkpoint (`bool`, *optional*, defaults to False):
Whether to enable checkpointing.
dim_embed (`List[int]`, *optional*, defaults to [256, 512, 1024, 2048]):
The dimension of the embedding layer.
num_heads (`List[int]`, *optional*, defaults to [8, 16, 32, 64]):
The number of attention heads.
num_groups (`List[int]`, *optional*, defaults to [8, 16, 32, 64]):
The number of groups.
depths (`List[int]`, *optional*, defaults to [1, 1, 9, 1]):
The depth of the model.
window_size (`int`, *optional*, defaults to 12):
The window size of the model.
projection_dim (`int`, *optional*, defaults to 1024):
The dimension of the projection layer.
visual_temporal_embedding (`dict`, *optional*):
The configuration of the visual temporal embedding.
image_pos_embed (`dict`, *optional*):
The configuration of the image position embedding.
image_feature_source (`List[str]`, *optional*, defaults to ["spatial_avg_pool", "temporal_avg_pool"]):
The source of the image feature.
Example:
```python
>>> from transformers import Florence2VisionConfig, Florence2VisionModel
>>> # Initializing a Florence2 Vision style configuration
>>> configuration = Florence2VisionConfig()
>>> # Initializing a model (with random weights)
>>> model = Florence2VisionModel(configuration)
>>> # Accessing the model configuration
>>> configuration = model.config
```"""
model_type = "davit"
keys_to_ignore_at_inference = ["past_key_values"]
def __init__(
self,
drop_path_rate=0.1,
patch_size=None,
patch_stride=None,
patch_padding=None,
patch_prenorm=None,
enable_checkpoint=False,
dim_embed=None,
num_heads=None,
num_groups=None,
depths=None,
window_size=12,
projection_dim=1024,
visual_temporal_embedding=None,
image_pos_embed=None,
image_feature_source=None,
**kwargs,
):
self.drop_path_rate = drop_path_rate
self.patch_size = patch_size if patch_size is not None else [7, 3, 3, 3]
self.patch_stride = patch_stride if patch_stride is not None else [4, 2, 2, 2]
self.patch_padding = patch_padding if patch_padding is not None else [3, 1, 1, 1]
self.patch_prenorm = patch_prenorm if patch_prenorm is not None else [False, True, True, True]
self.enable_checkpoint = enable_checkpoint
self.dim_embed = dim_embed if dim_embed is not None else [256, 512, 1024, 2048]
self.num_heads = num_heads if num_heads is not None else [8, 16, 32, 64]
self.num_groups = num_groups if num_groups is not None else [8, 16, 32, 64]
self.depths = depths if depths is not None else [1, 1, 9, 1]
self.window_size = window_size
self.projection_dim = projection_dim
if visual_temporal_embedding is None:
visual_temporal_embedding = {
"type": "COSINE",
"max_temporal_embeddings": 100,
}
self.visual_temporal_embedding = visual_temporal_embedding
if image_pos_embed is None:
image_pos_embed = {
"type": "learned_abs_2d",
"max_pos_embeddings": 1000,
}
self.image_pos_embed = image_pos_embed
self.image_feature_source = (
image_feature_source
if image_feature_source is not None
else ["spatial_avg_pool", "temporal_avg_pool"]
)
super().__init__(**kwargs)
class Florence2LanguageConfig(PretrainedConfig):
r"""
This is the configuration class to store the configuration of a [`Florence2LanguagePreTrainedModel`]. It is used to instantiate a BART
model according to the specified arguments, defining the model architecture. Instantiating a configuration with the
defaults will yield a similar configuration to that of the BART
[facebook/bart-large](https://huggingface.co/facebook/bart-large) architecture.
Configuration objects inherit from [`PretrainedConfig`] and can be used to control the model outputs. Read the
documentation from [`PretrainedConfig`] for more information.
Args:
vocab_size (`int`, *optional*, defaults to 51289):
Vocabulary size of the Florence2Language model. Defines the number of different tokens that can be represented by the
`inputs_ids` passed when calling [`Florence2LanguageModel`].
d_model (`int`, *optional*, defaults to 1024):
Dimensionality of the layers and the pooler layer.
encoder_layers (`int`, *optional*, defaults to 12):
Number of encoder layers.
decoder_layers (`int`, *optional*, defaults to 12):
Number of decoder layers.
encoder_attention_heads (`int`, *optional*, defaults to 16):
Number of attention heads for each attention layer in the Transformer encoder.
decoder_attention_heads (`int`, *optional*, defaults to 16):
Number of attention heads for each attention layer in the Transformer decoder.
decoder_ffn_dim (`int`, *optional*, defaults to 4096):
Dimensionality of the "intermediate" (often named feed-forward) layer in decoder.
encoder_ffn_dim (`int`, *optional*, defaults to 4096):
Dimensionality of the "intermediate" (often named feed-forward) layer in decoder.
activation_function (`str` or `function`, *optional*, defaults to `"gelu"`):
The non-linear activation function (function or string) in the encoder and pooler. If string, `"gelu"`,
`"relu"`, `"silu"` and `"gelu_new"` are supported.
dropout (`float`, *optional*, defaults to 0.1):
The dropout probability for all fully connected layers in the embeddings, encoder, and pooler.
attention_dropout (`float`, *optional*, defaults to 0.0):
The dropout ratio for the attention probabilities.
activation_dropout (`float`, *optional*, defaults to 0.0):
The dropout ratio for activations inside the fully connected layer.
classifier_dropout (`float`, *optional*, defaults to 0.0):
The dropout ratio for classifier.
max_position_embeddings (`int`, *optional*, defaults to 1024):
The maximum sequence length that this model might ever be used with. Typically set this to something large
just in case (e.g., 512 or 1024 or 2048).
init_std (`float`, *optional*, defaults to 0.02):
The standard deviation of the truncated_normal_initializer for initializing all weight matrices.
encoder_layerdrop (`float`, *optional*, defaults to 0.0):
The LayerDrop probability for the encoder. See the [LayerDrop paper](see https://arxiv.org/abs/1909.11556)
for more details.
decoder_layerdrop (`float`, *optional*, defaults to 0.0):
The LayerDrop probability for the decoder. See the [LayerDrop paper](see https://arxiv.org/abs/1909.11556)
for more details.
scale_embedding (`bool`, *optional*, defaults to `False`):
Scale embeddings by diving by sqrt(d_model).
use_cache (`bool`, *optional*, defaults to `True`):
Whether or not the model should return the last key/values attentions (not used by all models).
num_labels (`int`, *optional*, defaults to 3):
The number of labels to use in [`Florence2LanguageForSequenceClassification`].
forced_eos_token_id (`int`, *optional*, defaults to 2):
The id of the token to force as the last generated token when `max_length` is reached. Usually set to
`eos_token_id`.
Example:
```python
>>> from transformers import Florence2LanguageConfig, Florence2LanguageModel
>>> # Initializing a Florence2 Language style configuration
>>> configuration = Florence2LanguageConfig()
>>> # Initializing a model (with random weights)
>>> model = Florence2LanguageModel(configuration)
>>> # Accessing the model configuration
>>> configuration = model.config
```"""
model_type = "florence2_language"
keys_to_ignore_at_inference = ["past_key_values"]
attribute_map = {"num_attention_heads": "encoder_attention_heads", "hidden_size": "d_model"}
def __init__(
self,
vocab_size=51289,
max_position_embeddings=1024,
encoder_layers=12,
encoder_ffn_dim=4096,
encoder_attention_heads=16,
decoder_layers=12,
decoder_ffn_dim=4096,
decoder_attention_heads=16,
encoder_layerdrop=0.0,
decoder_layerdrop=0.0,
activation_function="gelu",
d_model=1024,
dropout=0.1,
attention_dropout=0.0,
activation_dropout=0.0,
init_std=0.02,
classifier_dropout=0.0,
scale_embedding=False,
use_cache=True,
num_labels=3,
pad_token_id=1,
bos_token_id=0,
eos_token_id=2,
is_encoder_decoder=True,
decoder_start_token_id=2,
forced_eos_token_id=2,
**kwargs,
):
self.vocab_size = vocab_size
self.max_position_embeddings = max_position_embeddings
self.d_model = d_model
self.encoder_ffn_dim = encoder_ffn_dim
self.encoder_layers = encoder_layers
self.encoder_attention_heads = encoder_attention_heads
self.decoder_ffn_dim = decoder_ffn_dim
self.decoder_layers = decoder_layers
self.decoder_attention_heads = decoder_attention_heads
self.dropout = dropout
self.attention_dropout = attention_dropout
self.activation_dropout = activation_dropout
self.activation_function = activation_function
self.init_std = init_std
self.encoder_layerdrop = encoder_layerdrop
self.decoder_layerdrop = decoder_layerdrop
self.classifier_dropout = classifier_dropout
self.use_cache = use_cache
self.num_hidden_layers = encoder_layers
self.scale_embedding = scale_embedding # scale factor will be sqrt(d_model) if True
super().__init__(
num_labels=num_labels,
pad_token_id=pad_token_id,
bos_token_id=bos_token_id,
eos_token_id=eos_token_id,
is_encoder_decoder=is_encoder_decoder,
decoder_start_token_id=decoder_start_token_id,
forced_eos_token_id=forced_eos_token_id,
**kwargs,
)
# ensure backward compatibility for BART CNN models
if self.forced_bos_token_id is None and kwargs.get("force_bos_token_to_be_generated", False):
self.forced_bos_token_id = self.bos_token_id
warnings.warn(
f"Please make sure the config includes `forced_bos_token_id={self.bos_token_id}` in future versions. "
"The config can simply be saved and uploaded again to be fixed.",
stacklevel=2,
)
class Florence2Config(PretrainedConfig):
r"""
This is the configuration class to store the configuration of a [`Florence2ForConditionalGeneration`]. It is used to instantiate an
Florence-2 model according to the specified arguments, defining the model architecture.
Configuration objects inherit from [`PretrainedConfig`] and can be used to control the model outputs. Read the
documentation from [`PretrainedConfig`] for more information.
Args:
vision_config (`Florence2VisionConfig`, *optional*):
Custom vision config or dict
text_config (`Union[AutoConfig, dict]`, *optional*):
The config object of the text backbone.
ignore_index (`int`, *optional*, defaults to -100):
The ignore index for the loss function.
vocab_size (`int`, *optional*, defaults to 51289):
Vocabulary size of the Florence2model. Defines the number of different tokens that can be represented by the
`inputs_ids` passed when calling [`~Florence2ForConditionalGeneration`]
projection_dim (`int`, *optional*, defaults to 1024):
Dimension of the multimodal projection space.
Example:
```python
>>> from transformers import Florence2ForConditionalGeneration, Florence2Config, CLIPVisionConfig, BartConfig
>>> # Initializing a clip-like vision config
>>> vision_config = CLIPVisionConfig()
>>> # Initializing a Bart config
>>> text_config = BartConfig()
>>> # Initializing a Florence-2 configuration
>>> configuration = Florence2Config(vision_config, text_config)
>>> # Initializing a model from the florence-2 configuration
>>> model = Florence2ForConditionalGeneration(configuration)
>>> # Accessing the model configuration
>>> configuration = model.config
```"""
model_type = "florence2"
is_composition = False
def __init__(
self,
vision_config=None,
text_config=None,
ignore_index=-100,
vocab_size=51289,
projection_dim=1024,
**kwargs,
):
self.ignore_index = ignore_index
self.vocab_size = vocab_size
self.projection_dim = projection_dim
if vision_config is not None:
vision_config = Florence2VisionConfig(**vision_config)
self.vision_config = vision_config
self.text_config = text_config
if text_config is not None:
self.text_config = Florence2LanguageConfig(**text_config)
super().__init__(**kwargs)

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#!/usr/bin/env python
# ------------------------------------------------------------------------------
# Copyright 2025 The HuggingFace Inc. team and 2toINF (https://github.com/2toINF)
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
# ------------------------------------------------------------------------------
from __future__ import annotations
from dataclasses import dataclass, field
from typing import TYPE_CHECKING, Any
from lerobot.configs.policies import PreTrainedConfig
from lerobot.configs.types import FeatureType, NormalizationMode, PolicyFeature
from lerobot.optim.optimizers import XVLAAdamWConfig
from lerobot.optim.schedulers import CosineDecayWithWarmupSchedulerConfig
from lerobot.utils.constants import OBS_IMAGES
# Conditional import for type checking and lazy loading
from lerobot.utils.import_utils import _transformers_available
if TYPE_CHECKING or _transformers_available:
from .configuration_florence2 import Florence2Config
else:
Florence2Config = None
@PreTrainedConfig.register_subclass("xvla")
@dataclass
class XVLAConfig(PreTrainedConfig):
"""
Configuration class for the XVLA (Extended Vision-Language-Action) policy so it can
plug into the LeRobot training stack.
The config mirrors the knobs exposed in the original XVLA repository but also
declares the input/output feature contract required by LeRobot.
"""
# Input / output structure
n_obs_steps: int = 1
chunk_size: int = 32
n_action_steps: int = 32
dtype: str = "float32" # Options: "bfloat16", "float32"
normalization_mapping: dict[str, NormalizationMode] = field(
default_factory=lambda: {
"VISUAL": NormalizationMode.IDENTITY,
"STATE": NormalizationMode.IDENTITY,
"ACTION": NormalizationMode.IDENTITY,
}
)
# Florence2 backbone and tokenizer configuration
florence_config: dict[str, Any] = field(default_factory=dict)
tokenizer_name: str = "facebook/bart-large"
tokenizer_max_length: int = 64
tokenizer_padding_side: str = "right"
pad_language_to: str = "max_length"
# Transformer head
hidden_size: int = 1024
depth: int = 24
num_heads: int = 16
mlp_ratio: float = 4.0
num_domains: int = 30
len_soft_prompts: int = 32
dim_time: int = 32
max_len_seq: int = 512
use_hetero_proj: bool = False
# Action & proprioception
action_mode: str = "ee6d"
num_denoising_steps: int = 10
use_proprio: bool = True
max_state_dim: int = 32
max_action_dim: int = 20 # Maximum action dimension for padding (used by "auto" action mode)
domain_feature_key: str | None = None
# Vision preprocessing
resize_imgs_with_padding: tuple[int, int] | None = None
num_image_views: int | None = None
empty_cameras: int = 0
# Freezing options for VLM components
# By default, VLM encoders are frozen and only policy transformer + soft prompts train
freeze_vision_encoder: bool = False # Freeze VLM vision encoder weights
freeze_language_encoder: bool = False # Freeze VLM language encoder weights
train_policy_transformer: bool = True # Allow policy transformer to train
train_soft_prompts: bool = True # Allow soft prompts to train
# Training presets
optimizer_lr: float = 1e-4
optimizer_betas: tuple[float, float] = (0.9, 0.99)
optimizer_eps: float = 1e-8
optimizer_weight_decay: float = 0.0
optimizer_grad_clip_norm: float = 10.0
# Soft-prompt LR settings (for optional warm-up)
optimizer_soft_prompt_lr_scale: float = 1.0 # Scale factor for soft-prompt LR
optimizer_soft_prompt_warmup_lr_scale: float | None = None # Start scale for warmup (e.g., 0.01)
scheduler_warmup_steps: int = 1_000
scheduler_decay_steps: int = 30_000
scheduler_decay_lr: float = 2.5e-6
def __post_init__(self) -> None:
super().__post_init__()
if self.chunk_size <= 0:
raise ValueError("`chunk_size` must be strictly positive.")
if self.n_action_steps > self.chunk_size:
raise ValueError(
f"`n_action_steps` ({self.n_action_steps}) must be <= `chunk_size` ({self.chunk_size})."
)
if self.num_image_views is not None and self.num_image_views <= 0:
raise ValueError("`num_image_views` must be > 0 when specified.")
if self.dtype not in ["bfloat16", "float32"]:
raise ValueError(f"Invalid dtype: {self.dtype}")
self._florence_config_obj: Florence2Config | None = None
def get_florence_config(self) -> Florence2Config:
"""
Build (and cache) the Florence2 transformer config that should back the VLM.
"""
if self._florence_config_obj is None:
config_dict = dict(self.florence_config)
if "vision_config" not in config_dict or config_dict["vision_config"] is None:
raise ValueError("vision_config is required")
if "text_config" not in config_dict or config_dict["text_config"] is None:
raise ValueError("text_config is required")
self._florence_config_obj = Florence2Config(**config_dict)
return self._florence_config_obj
def validate_features(self) -> None:
if not self.image_features:
raise ValueError("XVLA requires at least one visual feature in the inputs.")
if self.use_proprio and self.robot_state_feature is None:
raise ValueError("`use_proprio=True` requires a proprioceptive state feature.")
if self.num_image_views is None:
self.num_image_views = len(self.image_features) + self.empty_cameras
else:
self.num_image_views = max(self.num_image_views, len(self.image_features) + self.empty_cameras)
if self.empty_cameras > 0:
height, width = (480, 640)
if self.resize_imgs_with_padding is not None:
height, width = self.resize_imgs_with_padding
for idx in range(self.empty_cameras):
key = f"{OBS_IMAGES}.empty_camera_{idx}"
if key not in self.input_features:
self.input_features[key] = PolicyFeature(
type=FeatureType.VISUAL,
shape=(3, height, width),
)
def get_optimizer_preset(self) -> XVLAAdamWConfig:
"""Return the XVLA-specific optimizer with differential learning rates.
This optimizer applies:
- 1/10 LR for VLM parameters (stable optimization)
- Full LR for transformer/action head
- Configurable LR for soft-prompts (with optional warm-up)
"""
return XVLAAdamWConfig(
lr=self.optimizer_lr,
betas=self.optimizer_betas,
eps=self.optimizer_eps,
weight_decay=self.optimizer_weight_decay,
grad_clip_norm=self.optimizer_grad_clip_norm,
soft_prompt_lr_scale=self.optimizer_soft_prompt_lr_scale,
soft_prompt_warmup_lr_scale=self.optimizer_soft_prompt_warmup_lr_scale,
)
def get_scheduler_preset(self) -> CosineDecayWithWarmupSchedulerConfig:
return CosineDecayWithWarmupSchedulerConfig(
peak_lr=self.optimizer_lr,
decay_lr=self.scheduler_decay_lr,
num_warmup_steps=self.scheduler_warmup_steps,
num_decay_steps=self.scheduler_decay_steps,
)
@property
def observation_delta_indices(self) -> list[int] | None:
return None
@property
def action_delta_indices(self) -> list[int]:
return list(range(self.chunk_size))
@property
def reward_delta_indices(self) -> list[int] | None:
return None

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#!/usr/bin/env python
# ------------------------------------------------------------------------------
# Copyright 2025 The HuggingFace Inc. team and 2toINF (https://github.com/2toINF)
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
# ------------------------------------------------------------------------------
from __future__ import annotations
import builtins
import logging
import os
from collections import deque
from pathlib import Path
import torch
import torch.nn.functional as F # noqa: N812
from torch import Tensor, nn
from lerobot.configs.policies import PreTrainedConfig
from lerobot.policies.pretrained import PreTrainedPolicy, T
from lerobot.policies.utils import populate_queues
from lerobot.utils.constants import ACTION, OBS_LANGUAGE_TOKENS, OBS_STATE
from .action_hub import build_action_space
from .configuration_florence2 import Florence2Config
from .configuration_xvla import XVLAConfig
from .modeling_florence2 import Florence2ForConditionalGeneration
from .soft_transformer import SoftPromptedTransformer
class XVLAModel(nn.Module):
"""
XVLA backbone that stitches Florence-2 embeddings with the temporal/action transformer head.
"""
def __init__(
self,
config: XVLAConfig,
florence_config: Florence2Config,
proprio_dim: int,
) -> None:
super().__init__()
self.config = config
self.chunk_size: int = config.chunk_size
self.use_proprio: bool = config.use_proprio
# Build action space with auto-detection for "auto" mode
if config.action_mode.lower() == "auto":
# Auto-detect real action dim from config.action_feature
real_dim = (
config.action_feature.shape[-1]
if config.action_feature is not None
else config.max_action_dim
)
self.action_space = build_action_space(
config.action_mode.lower(),
real_dim=real_dim,
max_dim=config.max_action_dim,
)
else:
self.action_space = build_action_space(config.action_mode.lower())
self.dim_action = self.action_space.dim_action
self.dim_proprio = proprio_dim
self.vlm = Florence2ForConditionalGeneration(florence_config)
if hasattr(self.vlm, "language_model"):
lm = self.vlm.language_model
if hasattr(lm, "model") and hasattr(lm.model, "decoder"):
del lm.model.decoder
if hasattr(lm, "lm_head"):
del lm.lm_head
projection_dim = getattr(self.vlm.config, "projection_dim", None)
if projection_dim is None:
raise ValueError("Florence2 config must provide `projection_dim` for multimodal fusion.")
self.transformer = SoftPromptedTransformer(
hidden_size=config.hidden_size,
multi_modal_input_size=projection_dim,
depth=config.depth,
num_heads=config.num_heads,
mlp_ratio=config.mlp_ratio,
num_domains=config.num_domains,
dim_action=self.dim_action,
dim_propio=self.dim_proprio,
len_soft_prompts=config.len_soft_prompts,
dim_time=config.dim_time,
max_len_seq=config.max_len_seq,
use_hetero_proj=config.use_hetero_proj,
)
# Apply freezing based on config
self._apply_freezing()
# Apply dtype casting based on config
self._apply_dtype()
def _get_target_dtype(self) -> torch.dtype:
"""Get the target dtype based on config."""
if self.config.dtype == "bfloat16":
return torch.bfloat16
return torch.float32
def _apply_dtype(self) -> None:
"""
Apply dtype casting to model components based on config.
"""
target_dtype = self._get_target_dtype()
self.to(dtype=target_dtype)
def _apply_freezing(self) -> None:
"""
Freeze VLM vision and language encoders based on config options.
Keep only policy transformer and soft prompts trainable.
"""
# Freeze vision encoder
if self.config.freeze_vision_encoder and hasattr(self.vlm, "vision_tower"):
for param in self.vlm.vision_tower.parameters():
param.requires_grad = False
# Freeze language encoder
if self.config.freeze_language_encoder and hasattr(self.vlm, "language_model"):
lm = self.vlm.language_model
# Freeze encoder
if hasattr(lm, "model") and hasattr(lm.model, "encoder"):
for param in lm.model.encoder.parameters():
param.requires_grad = False
# Freeze shared embeddings
if hasattr(lm, "model") and hasattr(lm.model, "shared"):
for param in lm.model.shared.parameters():
param.requires_grad = False
# Freeze or unfreeze policy transformer
if not self.config.train_policy_transformer:
for name, param in self.transformer.named_parameters():
if "soft_prompts" not in name:
param.requires_grad = False
# Freeze or unfreeze soft prompts
if not self.config.train_soft_prompts and hasattr(self.transformer, "soft_prompt_hub"):
for param in self.transformer.soft_prompt_hub.parameters():
param.requires_grad = False
def forward_vlm(
self,
input_ids: torch.LongTensor,
pixel_values: torch.FloatTensor,
image_mask: torch.Tensor,
) -> dict[str, torch.Tensor]:
"""
Encode text and multi-view images via Florence2 encoder.
"""
batch_size, num_views = pixel_values.shape[:2]
flat_mask = image_mask.view(-1).to(dtype=torch.bool)
flat_images = pixel_values.flatten(0, 1)
num_valid = int(flat_mask.sum().item())
if num_valid == 0:
raise ValueError("At least one image view must be valid per batch.")
valid_images = flat_images[flat_mask]
valid_feats = self.vlm._encode_image(valid_images)
tokens_per_view, hidden_dim = valid_feats.shape[1:]
image_features = valid_feats.new_zeros((batch_size * num_views, tokens_per_view, hidden_dim))
image_features[flat_mask] = valid_feats
image_features = image_features.view(batch_size, num_views, tokens_per_view, hidden_dim)
inputs_embeds = self.vlm.get_input_embeddings()(input_ids)
merged_embeds, attention_mask = self.vlm._merge_input_ids_with_image_features(
image_features[:, 0],
inputs_embeds,
)
enc_out = self.vlm.language_model.model.encoder(
attention_mask=attention_mask,
inputs_embeds=merged_embeds,
)[0]
aux_visual_inputs = image_features[:, 1:].reshape(batch_size, -1, hidden_dim)
return {"vlm_features": enc_out, "aux_visual_inputs": aux_visual_inputs}
def forward(
self,
input_ids: torch.LongTensor,
image_input: torch.FloatTensor,
image_mask: torch.Tensor,
domain_id: torch.LongTensor,
proprio: torch.Tensor,
action: torch.Tensor,
) -> dict[str, torch.Tensor]:
"""
Forward pass for the XVLA model.
"""
target_dtype = self._get_target_dtype()
image_input = image_input.to(dtype=target_dtype)
proprio = proprio.to(dtype=target_dtype)
action = action.to(dtype=target_dtype)
enc = self.forward_vlm(input_ids, image_input, image_mask)
batch_size = input_ids.shape[0]
t = (
torch.rand(1, device=input_ids.device, dtype=target_dtype)
+ torch.arange(batch_size, device=input_ids.device, dtype=target_dtype) / batch_size
) % (1 - 1e-5)
action_noisy = torch.randn_like(action) * t.view(-1, 1, 1) + action * (1 - t).view(-1, 1, 1)
proprio_m, action_noisy_m = self.action_space.preprocess(proprio, action_noisy)
pred_action = self.transformer(
domain_id=domain_id,
action_with_noise=action_noisy_m,
t=t,
proprio=proprio_m,
**enc,
)
return self.action_space.compute_loss(pred_action, action)
@torch.no_grad()
def generate_actions(
self,
input_ids: torch.LongTensor,
image_input: torch.FloatTensor,
image_mask: torch.Tensor,
domain_id: torch.LongTensor,
proprio: torch.Tensor,
steps: int,
) -> torch.Tensor:
self.eval()
target_dtype = self._get_target_dtype()
image_input = image_input.to(dtype=target_dtype)
proprio = proprio.to(dtype=target_dtype)
enc = self.forward_vlm(input_ids, image_input, image_mask)
batch_size = input_ids.shape[0]
action_dim = self.dim_action
x1 = torch.randn(batch_size, self.chunk_size, action_dim, device=proprio.device, dtype=target_dtype)
action = torch.zeros_like(x1)
steps = max(1, int(steps))
for i in range(steps, 0, -1):
t = torch.full((batch_size,), i / steps, device=proprio.device, dtype=target_dtype)
x_t = x1 * t.view(-1, 1, 1) + action * (1 - t).view(-1, 1, 1)
proprio_m, x_t_m = self.action_space.preprocess(proprio, x_t)
action = self.transformer(
domain_id=domain_id,
action_with_noise=x_t_m,
proprio=proprio_m,
t=t,
**enc,
)
return self.action_space.postprocess(action)
class XVLAPolicy(PreTrainedPolicy):
"""LeRobot-compliant wrapper built around the XVLA model."""
config_class = XVLAConfig
name = "xvla"
def __init__(self, config: XVLAConfig):
super().__init__(config)
config.validate_features()
florence_config = config.get_florence_config()
proprio_dim = config.max_state_dim if config.use_proprio else 0
self.model = XVLAModel(config=config, florence_config=florence_config, proprio_dim=proprio_dim)
self.reset()
def reset(self) -> None:
self._queues = {
ACTION: deque(maxlen=self.config.n_action_steps),
}
def get_optim_params(self) -> dict:
"""Return trainable named parameters for optimization.
Returns a dict of name -> param for all trainable parameters.
This enables the xvla-adamw optimizer to apply differential learning rates
based on parameter names (e.g., 1/10 LR for VLM components).
"""
return dict(filter(lambda kv: kv[1].requires_grad, self.named_parameters()))
def _prepare_state(self, batch: dict[str, Tensor], batch_size: int, device: torch.device) -> Tensor:
if not self.config.use_proprio or OBS_STATE not in batch:
return torch.zeros(batch_size, 0, device=device)
state = batch[OBS_STATE]
if state.ndim > 2:
state = state[:, -1, :]
return pad_vector(state, self.model.dim_proprio)
def _prepare_images(self, batch: dict[str, Tensor]) -> tuple[Tensor, Tensor]:
present_img_keys = [key for key in self.config.image_features if key in batch]
if len(present_img_keys) == 0:
raise ValueError(
"All image features are missing from the batch. "
f"Batch keys: {list(batch.keys())}, expected at least one of {list(self.config.image_features)}."
)
images = []
masks = []
for key in present_img_keys:
img = batch[key][:, -1] if batch[key].ndim == 5 else batch[key]
if self.config.resize_imgs_with_padding is not None:
img = resize_with_pad(img, *self.config.resize_imgs_with_padding)
images.append(img)
masks.append(torch.ones(img.size(0), dtype=torch.bool, device=img.device))
stacked_imgs = torch.stack(images, dim=1)
stacked_masks = torch.stack(masks, dim=1)
total_views = self.config.num_image_views or stacked_imgs.size(1)
total_views = max(total_views, stacked_imgs.size(1))
num_pad = total_views - stacked_imgs.size(1)
if num_pad > 0:
pad_shape = (stacked_imgs.size(0), num_pad, *stacked_imgs.shape[2:])
pad_imgs = stacked_imgs.new_zeros(pad_shape)
pad_masks = stacked_masks.new_zeros((stacked_masks.size(0), num_pad))
stacked_imgs = torch.cat([stacked_imgs, pad_imgs], dim=1)
stacked_masks = torch.cat([stacked_masks, pad_masks], dim=1)
return stacked_imgs, stacked_masks
def _get_domain_id(self, batch: dict[str, Tensor], batch_size: int, device: torch.device) -> Tensor:
candidate = None
if self.config.domain_feature_key and self.config.domain_feature_key in batch:
candidate = batch[self.config.domain_feature_key]
elif "domain_id" in batch:
candidate = batch["domain_id"]
if candidate is None:
return torch.zeros(batch_size, dtype=torch.long, device=device)
if not isinstance(candidate, torch.Tensor):
candidate = torch.as_tensor(candidate, device=device)
else:
candidate = candidate.to(device=device)
if candidate.ndim == 0:
candidate = candidate.expand(batch_size)
if candidate.ndim > 1:
candidate = candidate.view(candidate.shape[0], -1)[:, 0]
if candidate.shape[0] != batch_size:
candidate = candidate.expand(batch_size)
return candidate.to(dtype=torch.long)
def _prepare_action_targets(self, batch: dict[str, Tensor]) -> Tensor:
if ACTION not in batch:
raise ValueError("Batch is missing action targets required for training.")
actions = batch[ACTION]
if actions.ndim == 2:
actions = actions.unsqueeze(1)
actions = pad_tensor_along_dim(actions, self.config.chunk_size, dim=1)
if actions.shape[-1] != self.model.dim_action:
actions = pad_vector(actions, self.model.dim_action)
return actions
def _build_model_inputs(self, batch: dict[str, Tensor]) -> dict[str, Tensor]:
input_ids = batch[OBS_LANGUAGE_TOKENS]
batch_size = input_ids.shape[0]
images, image_mask = self._prepare_images(batch)
domain_id = self._get_domain_id(batch, batch_size, images.device)
proprio = self._prepare_state(batch, batch_size, images.device)
return {
"input_ids": input_ids,
"image_input": images,
"image_mask": image_mask,
"domain_id": domain_id,
"proprio": proprio,
}
def forward(self, batch: dict[str, Tensor]) -> tuple[Tensor, dict]:
inputs = self._build_model_inputs(batch)
targets = self._prepare_action_targets(batch)
losses = self.model(action=targets, **inputs)
total_loss = sum(losses.values())
log_dict = {k: v.detach().item() for k, v in losses.items()}
log_dict["loss"] = total_loss.detach().item()
return total_loss, log_dict
def _get_action_chunk(self, batch: dict[str, Tensor]) -> Tensor:
inputs = self._build_model_inputs(batch)
actions = self.model.generate_actions(**inputs, steps=self.config.num_denoising_steps)
return actions
@torch.no_grad()
def predict_action_chunk(self, batch: dict[str, Tensor], noise: Tensor | None = None) -> Tensor: # noqa: ARG002
self.eval()
self._queues = populate_queues(self._queues, batch, exclude_keys=[ACTION])
return self._get_action_chunk(batch)
@torch.no_grad()
def select_action(self, batch: dict[str, Tensor], noise: Tensor | None = None) -> Tensor: # noqa: ARG002
self.eval()
self._queues = populate_queues(self._queues, batch, exclude_keys=[ACTION])
if len(self._queues[ACTION]) == 0:
actions = self._get_action_chunk(batch)
self._queues[ACTION].extend(actions.transpose(0, 1)[: self.config.n_action_steps])
return self._queues[ACTION].popleft()
@classmethod
def from_pretrained(
cls: builtins.type[T],
pretrained_name_or_path: str | Path,
*,
config: PreTrainedConfig | None = None,
force_download: bool = False,
resume_download: bool | None = None,
proxies: dict | None = None,
token: str | bool | None = None,
cache_dir: str | Path | None = None,
local_files_only: bool = False,
revision: str | None = None,
strict: bool = False,
**kwargs,
):
"""
Loads XVLA model weights with:
- automatic prefix 'model.' added to all keys
- skip list for layers that should remain randomly initialized
"""
import safetensors.torch
# step 1: load config
# TODO: jadechoghari, fix this
if config is None:
config = PreTrainedConfig.from_pretrained(
pretrained_name_or_path=pretrained_name_or_path,
force_download=force_download,
resume_download=resume_download,
proxies=proxies,
token=token,
cache_dir=cache_dir,
local_files_only=local_files_only,
revision=revision,
**kwargs,
)
model_id = str(pretrained_name_or_path)
instance = cls(config, **kwargs)
# step 2: locate model.safetensors
if os.path.isdir(model_id):
logging.info("Loading weights from local directory")
model_file = os.path.join(model_id, "model.safetensors")
else:
try:
from huggingface_hub import hf_hub_download
from huggingface_hub.utils import HfHubHTTPError
model_file = hf_hub_download(
repo_id=model_id,
filename="model.safetensors",
revision=revision,
cache_dir=cache_dir,
force_download=force_download,
proxies=proxies,
resume_download=resume_download,
token=token,
local_files_only=local_files_only,
)
except HfHubHTTPError as e:
raise FileNotFoundError(f"model.safetensors not found on the Hub at {model_id}") from e
logging.info(f"Loading checkpoint from {model_file}")
# step 3: load state dict
state_dict = safetensors.torch.load_file(model_file)
encoder_key = "model.vlm.language_model.model.encoder.embed_tokens.weight"
shared_key = "model.vlm.language_model.model.shared.weight"
if encoder_key in state_dict:
state_dict[shared_key] = state_dict[encoder_key]
# or deepcopy
# step 4: load into instance
instance.load_state_dict(state_dict, strict=True)
logging.info("Loaded XVLA checkpoint")
# step 5: finalize
# Reapply dtype after loading state dict
instance.model._apply_dtype()
instance.to(config.device)
instance.eval()
return instance
def resize_with_pad(img: torch.Tensor, height: int, width: int, pad_value: float = 0.0) -> torch.Tensor:
if img.ndim != 4:
raise ValueError(f"(b,c,h,w) expected, but got {img.shape}")
current_height, current_width = img.shape[2:]
if current_height == height and current_width == width:
return img
ratio = max(current_width / width, current_height / height)
resized_height = int(current_height / ratio)
resized_width = int(current_width / ratio)
resized_img = F.interpolate(
img, size=(resized_height, resized_width), mode="bilinear", align_corners=False
)
pad_height = max(0, height - resized_height)
pad_width = max(0, width - resized_width)
padded_img = F.pad(resized_img, (pad_width, 0, pad_height, 0), value=pad_value)
return padded_img
def pad_vector(vector: Tensor, new_dim: int) -> Tensor:
if vector.shape[-1] == new_dim:
return vector
if new_dim == 0:
shape = list(vector.shape)
shape[-1] = 0
return vector.new_zeros(*shape)
shape = list(vector.shape)
current_dim = shape[-1]
shape[-1] = new_dim
new_vector = vector.new_zeros(*shape)
length = min(current_dim, new_dim)
new_vector[..., :length] = vector[..., :length]
return new_vector
def pad_tensor_along_dim(tensor: Tensor, target_len: int, dim: int = 1) -> Tensor:
current_len = tensor.size(dim)
if current_len == target_len:
return tensor
if current_len > target_len:
slices = [slice(None)] * tensor.dim()
slices[dim] = slice(0, target_len)
return tensor[tuple(slices)]
pad_shape = list(tensor.shape)
pad_shape[dim] = target_len - current_len
pad_tensor = tensor.new_zeros(pad_shape)
return torch.cat([tensor, pad_tensor], dim=dim)

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src/lerobot/policies/xvla/processor_xvla.py Normal file
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@@ -0,0 +1,554 @@
# ------------------------------------------------------------------------------
# Copyright 2025 The HuggingFace Inc. team and 2toINF (https://github.com/2toINF)
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
# ------------------------------------------------------------------------------
from dataclasses import dataclass
from typing import Any
import numpy as np
import torch
from lerobot.configs.types import PipelineFeatureType, PolicyFeature
from lerobot.datasets.factory import IMAGENET_STATS
from lerobot.policies.xvla.configuration_xvla import XVLAConfig
from lerobot.policies.xvla.utils import rotate6d_to_axis_angle
from lerobot.processor import (
AddBatchDimensionProcessorStep,
DeviceProcessorStep,
NormalizerProcessorStep,
ObservationProcessorStep,
PolicyAction,
PolicyProcessorPipeline,
ProcessorStep,
ProcessorStepRegistry,
RenameObservationsProcessorStep,
TokenizerProcessorStep,
UnnormalizerProcessorStep,
)
from lerobot.processor.converters import policy_action_to_transition, transition_to_policy_action
from lerobot.processor.core import EnvTransition, TransitionKey
from lerobot.utils.constants import (
OBS_IMAGES,
OBS_STATE,
POLICY_POSTPROCESSOR_DEFAULT_NAME,
POLICY_PREPROCESSOR_DEFAULT_NAME,
)
def make_xvla_pre_post_processors(
config: XVLAConfig,
dataset_stats: dict[str, dict[str, torch.Tensor]] | None = None,
) -> tuple[
PolicyProcessorPipeline[dict[str, Any], dict[str, Any]],
PolicyProcessorPipeline[PolicyAction, PolicyAction],
]:
"""
Build the LeRobot processor pipelines for XVLA.
"""
features = {**config.input_features, **config.output_features}
input_steps = [
RenameObservationsProcessorStep(rename_map={}),
AddBatchDimensionProcessorStep(),
TokenizerProcessorStep(
tokenizer_name=config.tokenizer_name,
max_length=config.tokenizer_max_length,
padding=config.pad_language_to,
padding_side=config.tokenizer_padding_side,
),
XVLAImageToFloatProcessorStep(),
XVLAImageNetNormalizeProcessorStep(),
XVLAAddDomainIdProcessorStep(),
DeviceProcessorStep(device=config.device),
NormalizerProcessorStep(
features=features, norm_map=config.normalization_mapping, stats=dataset_stats
),
]
output_steps = [
UnnormalizerProcessorStep(
features=config.output_features,
norm_map=config.normalization_mapping,
stats=dataset_stats,
),
DeviceProcessorStep(device="cpu"),
]
return (
PolicyProcessorPipeline[dict[str, Any], dict[str, Any]](
steps=input_steps,
name=POLICY_PREPROCESSOR_DEFAULT_NAME,
),
PolicyProcessorPipeline[PolicyAction, PolicyAction](
steps=output_steps,
name=POLICY_POSTPROCESSOR_DEFAULT_NAME,
to_transition=policy_action_to_transition,
to_output=transition_to_policy_action,
),
)
# Custom XVLA processor steps
@dataclass
class LiberoProcessorStep(ObservationProcessorStep):
"""
Processes LIBERO observations into the LeRobot format.
This step handles the specific observation structure from LIBERO environments,
which includes nested robot_state dictionaries and image observations.
**State Processing:**
- Processes the `robot_state` dictionary which contains nested end-effector,
gripper, and joint information.
- Extracts and concatenates:
- End-effector position (3D)
- End-effector quaternion converted to axis-angle (3D)
- Gripper joint positions (2D)
- Maps the concatenated state to `"observation.state"`.
**Image Processing:**
- Rotates images by 180 degrees by flipping both height and width dimensions.
- This accounts for the HuggingFaceVLA/libero camera orientation convention.
"""
def _process_observation(self, observation):
"""
Processes both image and robot_state observations from LIBERO.
"""
processed_obs = observation.copy()
for key in list(processed_obs.keys()):
if key.startswith(f"{OBS_IMAGES}."):
img = processed_obs[key]
if key == f"{OBS_IMAGES}.image":
# Flip both H and W
img = torch.flip(img, dims=[2, 3])
processed_obs[key] = img
# Process robot_state into a flat state vector
if "observation.robot_state" in processed_obs:
robot_state = processed_obs.pop("observation.robot_state")
# Extract components
eef_pos = robot_state["eef"]["pos"] # (B, 3,)
eef_mat = robot_state["eef"]["mat"] # (B, 3, 3)
eef_rot6d = self._mat_to_rotate6d(eef_mat) # (B, 6)
extra = torch.zeros((eef_pos.shape[0], 1), dtype=torch.float32, device=eef_pos.device)
proprio_state = torch.cat((eef_pos, eef_rot6d, extra), dim=-1) # (B, 10)
state = torch.cat((proprio_state, torch.zeros_like(proprio_state)), dim=-1) # (B, 20)
# ensure float32
state = state.float()
if state.dim() == 1:
state = state.unsqueeze(0)
processed_obs[OBS_STATE] = state
return processed_obs
def transform_features(
self, features: dict[PipelineFeatureType, dict[str, PolicyFeature]]
) -> dict[PipelineFeatureType, dict[str, PolicyFeature]]:
"""
Transforms feature keys from the LIBERO format to the LeRobot standard.
"""
new_features: dict[PipelineFeatureType, dict[str, PolicyFeature]] = {}
# copy over non-STATE features
for ft, feats in features.items():
if ft != PipelineFeatureType.STATE:
new_features[ft] = feats.copy()
# rebuild STATE features
state_feats = {}
# add our new flattened state
state_feats["observation.state"] = PolicyFeature(
key="observation.state",
shape=(20,),
dtype="float32",
)
new_features[PipelineFeatureType.STATE] = state_feats
return new_features
def _mat_to_rotate6d(self, rot_mats: torch.Tensor) -> torch.Tensor:
"""
Convert batched rotation matrices (B, 3, 3) into 6D rotation representation (B, 6).
Args:
rot_mats (Tensor): Rotation matrices of shape (B, 3, 3)
Returns:
Tensor: 6D rotation representation, shape (B, 6)
Raises:
TypeError: if input is not a torch tensor
ValueError: if shape is not (B, 3, 3)
"""
if not isinstance(rot_mats, torch.Tensor):
raise TypeError(f"mat_to_rot6d expects a torch.Tensor, got {type(rot_mats)}")
if rot_mats.ndim != 3 or rot_mats.shape[1:] != (3, 3):
raise ValueError(f"mat_to_rot6d expects shape (B, 3, 3), got {tuple(rot_mats.shape)}")
rot_mats = rot_mats.to(torch.float32)
col1 = rot_mats[:, :3, 0] # (B, 3)
col2 = rot_mats[:, :3, 1] # (B, 3)
rot6d = torch.cat([col1, col2], dim=-1) # (B, 6)
return rot6d
def observation(self, observation):
return self._process_observation(observation)
@dataclass
@ProcessorStepRegistry.register(name="xvla_image_scale")
class XVLAImageScaleProcessorStep(ProcessorStep):
"""Scale image observations by 255 to convert from [0, 1] to [0, 255] range.
This processor step multiplies all image observations by 255, which is required
for XVLA models that expect images in uint8-like range.
Args:
image_keys: List of observation keys that contain images to scale.
If None, will automatically detect keys starting with "observation.images."
"""
image_keys: list[str] | None = None
def __call__(self, transition: EnvTransition) -> EnvTransition:
"""Scale image observations by 255."""
new_transition = transition.copy()
obs = new_transition.get(TransitionKey.OBSERVATION, {})
if obs is None:
return new_transition
# Make a copy of observations to avoid modifying the original
obs = obs.copy()
# Determine which keys to scale
keys_to_scale = self.image_keys
if keys_to_scale is None:
# Auto-detect image keys
keys_to_scale = [k for k in obs if k.startswith("observation.images.")]
# Scale each image
for key in keys_to_scale:
if key in obs and isinstance(obs[key], torch.Tensor):
obs[key] = obs[key] * 255
new_transition[TransitionKey.OBSERVATION] = obs
return new_transition
def transform_features(self, features):
"""Image scaling doesn't change feature structure."""
return features
def get_config(self) -> dict[str, Any]:
"""Return serializable configuration."""
return {
"image_keys": self.image_keys,
}
@dataclass
@ProcessorStepRegistry.register(name="xvla_image_to_float")
class XVLAImageToFloatProcessorStep(ProcessorStep):
"""Convert image observations from [0, 255] to [0, 1] range.
This processor step divides image observations by 255 to convert from uint8-like
range [0, 255] to float range [0, 1]. This is typically used when loading images
that are stored as uint8 values.
Args:
image_keys: List of observation keys that contain images to convert.
If None, will automatically detect keys starting with "observation.images."
validate_range: If True, validates that input values are in [0, 255] range (default: True)
Raises:
ValueError: If validate_range is True and image values are not in [0, 255] range.
"""
image_keys: list[str] | None = None
validate_range: bool = True
def __call__(self, transition: EnvTransition) -> EnvTransition:
"""Convert image observations from [0, 255] to [0, 1]."""
new_transition = transition.copy()
obs = new_transition.get(TransitionKey.OBSERVATION, {})
if obs is None:
return new_transition
# Make a copy of observations to avoid modifying the original
obs = obs.copy()
# Determine which keys to convert
keys_to_convert = self.image_keys
if keys_to_convert is None:
# Auto-detect image keys
keys_to_convert = [k for k in obs if k.startswith("observation.images.")]
# Convert each image
for key in keys_to_convert:
if key in obs and isinstance(obs[key], torch.Tensor):
tensor = obs[key]
min_val = tensor.min().item()
max_val = tensor.max().item()
if max_val <= 1.0:
obs[key] = tensor.float() # ensure float dtype, but no division
continue
# Validate that values are in [0, 255] range if requested
if self.validate_range and (min_val < 0.0 or max_val > 255.0):
raise ValueError(
f"Image '{key}' has values outside [0, 255] range: "
f"min={min_val:.4f}, max={max_val:.4f}. "
f"Cannot convert to [0, 1] range."
)
# Convert to float and divide by 255
obs[key] = tensor.float() / 255.0
new_transition[TransitionKey.OBSERVATION] = obs
return new_transition
def transform_features(self, features):
"""Image conversion doesn't change feature structure."""
return features
def get_config(self) -> dict[str, Any]:
"""Return serializable configuration."""
return {
"image_keys": self.image_keys,
"validate_range": self.validate_range,
}
@dataclass
@ProcessorStepRegistry.register(name="xvla_imagenet_normalize")
class XVLAImageNetNormalizeProcessorStep(ProcessorStep):
"""Normalize image observations using ImageNet statistics.
This processor step applies ImageNet normalization (mean and std) to image observations.
It validates that input values are in the [0, 1] range before normalizing.
The normalization formula is: (image - mean) / std
Args:
image_keys: List of observation keys that contain images to normalize.
If None, will automatically detect keys starting with "observation.images."
Raises:
ValueError: If image values are not in the [0, 1] range.
"""
image_keys: list[str] | None = None
def __call__(self, transition: EnvTransition) -> EnvTransition:
"""Normalize image observations using ImageNet statistics."""
new_transition = transition.copy()
obs = new_transition.get(TransitionKey.OBSERVATION, {})
if obs is None:
return new_transition
# Make a copy of observations to avoid modifying the original
obs = obs.copy()
# Determine which keys to normalize
keys_to_normalize = self.image_keys
if keys_to_normalize is None:
# Auto-detect image keys
keys_to_normalize = [k for k in obs if k.startswith("observation.images.")]
# Normalize each image
for key in keys_to_normalize:
if key in obs and isinstance(obs[key], torch.Tensor):
tensor = obs[key]
# Validate that values are in [0, 1] range
min_val = tensor.min().item()
max_val = tensor.max().item()
if min_val < 0.0 or max_val > 1.0:
raise ValueError(
f"Image '{key}' has values outside [0, 1] range: "
f"min={min_val:.4f}, max={max_val:.4f}. "
f"ImageNet normalization requires input values in [0, 1]."
)
# Apply ImageNet normalization
mean = torch.tensor(IMAGENET_STATS["mean"], device=tensor.device, dtype=tensor.dtype)
std = torch.tensor(IMAGENET_STATS["std"], device=tensor.device, dtype=tensor.dtype)
# Expand mean/std to match tensor dims (e.g., BCHW or BNCHW)
while mean.dim() < tensor.dim():
mean = mean.unsqueeze(0)
std = std.unsqueeze(0)
# Normalize: (image - mean) / std
obs[key] = (tensor - mean) / std
new_transition[TransitionKey.OBSERVATION] = obs
return new_transition
def transform_features(self, features):
"""ImageNet normalization doesn't change feature structure."""
return features
def get_config(self) -> dict[str, Any]:
"""Return serializable configuration."""
return {
"image_keys": self.image_keys,
}
@dataclass
@ProcessorStepRegistry.register(name="xvla_add_domain_id")
class XVLAAddDomainIdProcessorStep(ProcessorStep):
"""Add domain_id to complementary data.
This processor step adds a domain_id tensor to the complementary data,
which is used by XVLA to identify different robot embodiments or task domains.
Args:
domain_id: The domain ID to add (default: 3)
"""
domain_id: int = 0
def __call__(self, transition: EnvTransition) -> EnvTransition:
"""Add domain_id to complementary data."""
new_transition = transition.copy()
comp = new_transition.get(TransitionKey.COMPLEMENTARY_DATA, {})
comp = {} if comp is None else comp.copy()
# Infer batch size from observation tensors
obs = new_transition.get(TransitionKey.OBSERVATION, {})
batch_size = 1
if obs:
for v in obs.values():
if isinstance(v, torch.Tensor):
batch_size = v.shape[0]
break
# Add domain_id tensor
comp["domain_id"] = torch.tensor([int(self.domain_id)] * batch_size, dtype=torch.long)
new_transition[TransitionKey.COMPLEMENTARY_DATA] = comp
return new_transition
def transform_features(self, features):
"""Domain ID addition doesn't change feature structure."""
return features
def get_config(self) -> dict[str, Any]:
"""Return serializable configuration."""
return {
"domain_id": self.domain_id,
}
@dataclass
@ProcessorStepRegistry.register(name="xvla_rotation_6d_to_axis_angle")
class XVLARotation6DToAxisAngleProcessorStep(ProcessorStep):
"""Convert 6D rotation representation to axis-angle and reorganize action dimensions.
This processor step takes actions with 6D rotation representation and converts them to
axis-angle representation, reorganizing the action dimensions as:
- action[:, :3] -> target_eef (end-effector position)
- action[:, 3:9] -> 6D rotation (converted to axis-angle, 3D)
- action[:, 9:10] -> gripper action
Final output: [target_eef (3), axis_angle (3), gripper (1)] = 7D action
Args:
expected_action_dim: Expected input action dimension (default: 10, supports 6D rotation + extras)
"""
expected_action_dim: int = 10
def __call__(self, transition: EnvTransition) -> EnvTransition:
"""Convert 6D rotation to axis-angle in action."""
new_transition = transition.copy()
action = new_transition.get(TransitionKey.ACTION)
if action is None or not isinstance(action, torch.Tensor):
return new_transition
# Convert to numpy for processing
device = action.device
dtype = action.dtype
action_np = action.cpu().numpy()
# Extract components
# action shape: (B, D) where D >= 10
target_eef = action_np[:, :3] # (B, 3)
rotation_6d = action_np[:, 3:9] # (B, 6)
target_act = action_np[:, 9:10] # (B, 1)
# Convert 6D rotation to axis-angle
target_axis = rotate6d_to_axis_angle(rotation_6d) # (B, 3)
# Concatenate: [eef (3), axis_angle (3), gripper (1)] = 7D
action_np = np.concatenate([target_eef, target_axis, target_act], axis=-1)
# Convert gripper action to -1 or 1
action_np[:, -1] = np.where(action_np[:, -1] > 0.5, 1.0, -1.0)
# Convert back to tensor
action = torch.from_numpy(action_np).to(device=device, dtype=dtype)
new_transition[TransitionKey.ACTION] = action
return new_transition
def transform_features(self, features):
"""Rotation conversion changes action dimension from 10 to 7."""
# Note: This is a simplified version. In practice, you might want to
# update the action feature shape in the features dict.
return features
def get_config(self) -> dict[str, Any]:
"""Return serializable configuration."""
return {
"expected_action_dim": self.expected_action_dim,
}
def make_xvla_libero_pre_post_processors() -> tuple[
PolicyProcessorPipeline[dict[str, Any], dict[str, Any]],
PolicyProcessorPipeline[PolicyAction, PolicyAction],
]:
"""
Build the LeRobot processor pipelines for XVLA with LIBERO environment.
"""
pre_processor_steps: list[ProcessorStep] = []
post_processor_steps: list[ProcessorStep] = []
pre_processor_steps.extend(
[LiberoProcessorStep(), XVLAImageNetNormalizeProcessorStep(), XVLAAddDomainIdProcessorStep()]
)
post_processor_steps.extend([XVLARotation6DToAxisAngleProcessorStep()])
return (
PolicyProcessorPipeline[dict[str, Any], dict[str, Any]](
steps=pre_processor_steps,
),
PolicyProcessorPipeline[PolicyAction, PolicyAction](
steps=post_processor_steps,
),
)

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